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Metamorphic P–T–t paths of pelitic granulites of the Taihua metamorphic complex in the Mts. Huashan area and tectonothermal implications for the Palaeoproterozoic Trans-North China Orogen
Accepted Manuscript Metamorphic P–T–t paths of pelitic granulites of the Taihua metamorphic complex in the Mts. Huashan area and tectonothermal implications for the Palaeoproterozoic Trans-North China Orogen Guo-Dong Wang, Hao Y.C. Wang, Hong-Xu Chen, Jun-Sheng Lu, Bo Zhang, Van Tho Pham, Ji-Jun Zhang, Qing Zhang, Chun-Ming Wu PII: DOI: Reference:
S0301-9268(16)30387-4 http://dx.doi.org/10.1016/j.precamres.2016.12.008 PRECAM 4627
To appear in:
Precambrian Research
Received Date: Revised Date: Accepted Date:
14 September 2016 12 December 2016 25 December 2016
Please cite this article as: G-D. Wang, H.Y.C. Wang, H-X. Chen, J-S. Lu, B. Zhang, V. Tho Pham, J-J. Zhang, Q. Zhang, C-M. Wu, Metamorphic P–T–t paths of pelitic granulites of the Taihua metamorphic complex in the Mts. Huashan area and tectonothermal implications for the Palaeoproterozoic Trans-North China Orogen, Precambrian Research (2016), doi: http://dx.doi.org/10.1016/j.precamres.2016.12.008
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A revised original research manuscript submitted to Precambrian Research
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Metamorphic P–T–t paths of pelitic granulites of the Taihua metamorphic complex in the Mts. Huashan area and tectonothermal implications for the Palaeoproterozoic Trans-North China Orogen
8 9 10
Guo-Dong Wang
a,b*
, Hao Y.C. Wang b, Hong-Xu Chen b, Jun-Sheng Lu c, Bo
Zhang d, Van Tho Pham b, Ji-Jun Zhang e, Qing Zhang f, Chun-Ming Wu b
11
a
Institute of Oceanology, Chinese Academy of Sciences, Qingdao 266071, China
12
b
College of Earth Science, University of Chinese Academy of Sciences, P.O. Box
13
4588, Beijing 100049, China
14
c
15
China
16
d
China Corporation of Coal Geology Engineering, Beijing 100040, China
17
e
Shaanxi Center of Geological Survey, Xi’an 710068, China
18
f
Institute of Geomechanics, Chinese Academy of Geological Sciences, Beijing 100081,
19
China
Institute of Geology and Geophysics, Chinese Academy of Sciences, Beijing 100029,
20
*
Corresponding author at: Institute of Oceanology, Chinese Academy of Sciences, Qingdao 266071, China. E-mail address: [email protected] (G.-D. Wang). 1
21
22
ABSTRACT
23
Metamorphic evolution and geochronology of pelitic granulites were reported
24
for the first time in the Taihua metamorphic complex, Mts. Huashan area, southern
25
segment of the Trans-North China Orogen (TNCO). Three generations of
26
metamorphic mineral assemblages are recognized: (1) the prograde metamorphic
27
mineral assemblages (M1) are represented by mineral inclusions within the garnet
28
porphyroblasts; (2) the metamorphic peak assemblage (M2) are the garnet
29
porphyroblasts and minerals in the matrix (biotite + orthopyroxene + plagioclase +
30
quartz +
31
metamorphic mineral assemblages (M3) are represented by the symplectic
32
assemblages around the garnet porphyroblasts, resulted from decomposition reactions
33
between garnet rims and neighboring minerals in the matrix. Calculated by both
34
conventional thermobarometry and pseudosection modeling in the NCKFMASHT
35
system using the Perple_X technique, the P–T conditions of these three metamorphic
36
stages are constrained to be of 4–5 kbar/520–530 °C for the M1 stage, 6.8–8.6
37
kbar/730–810 °C for the M2 stage and 4.1–6.4 kbar/570–740 °C for the M3 stage,
38
respectively. The derived clockwise P–T paths imply that the Mts. Huashan terrane
39
involved in the subduction and subsequent collision between the Eastern and Western
40
Blocks of the North China Craton (NCC) along the Palaeoproterozoic Tran-North
41
China Orogen (TNCO). High resolution SIMS U–Pb dating of metamorphic zircons
42
reveals the metamorphic ages of 1.85–1.82 Ga. Combined with geochronological data
K-feldspar + ilmenite + zircon + magnetite); and (3) the retrograde
2
43
from the literature, it is concluded that the tectonothermal evolution between the
44
Eastern and Western Blocks started as early as ~1.97 Ga and lasted as late as 1.80 Ga.
45
Furthermore, the eastern Taihua complex records older metamorphic ages and higher
46
peak metamorphic pressures than those of the western Taihua complex, possibly
47
suggesting an eastward subduction model for the TNCO.
48
Keywords: Pelitic
49
path; North China Craton.
granulites; Taihua metamorphic complex; Metamorphic P–T–t
50 51 52 53 54 55 56 57 58 59 60 61 62 63 64
3
65 66
1. Introduction
67
Extensive studies of metamorphic P–T paths on various metamorphic terranes
68
worldwide indicate that different P–T paths are generally closely related to specific
69
tectonic environments or geodynamic processes the terranes underwent (England and
70
Richardson, 1977; England and Thompson, 1984; Bohlen, 1987, 1991; Harley, 1989;
71
Lu, 1991; Spear, 1992; Brown, 1993, 2009; Zhao et al., 1998, 2000a). The
72
anticlockwise P–T paths, especially for those containing near-isobaric cooling (IBC)
73
segments, are usually suggested to be the products of magmatic intrusion and
74
underplating in the regional setting of continental magmatic arc, hot spot or
75
continental rift (Sandiford and Powell, 1986; Bohlen, 1987, 1991; Harley, 1989; Lu,
76
1991; Zhao et al., 1998, 2000a). The clockwise P–T paths, especially for those
77
containing nearly isothermal decompression (ITD) segments, are generally interpreted
78
to be the results of subduction to continental collision followed by rapid uplift or
79
exhumation (England and Thompson, 1984; Bohlen, 1991; Lu, 1991; Brown, 1993;
80
Zhao et al., 2000a). To derive metamorphic P–T conditions and metamorphic P–T
81
paths, there are two general ways, i.e., thermobarometry and thermodynamic
82
pseudosection modeling. Thermobarometry is a conventional method and is based on
83
thermodynamic equilibrium preserved in the mineral assemblages. Thermodynamic
84
pseudosection modeling (e.g., Powell and Holland, 2008) is a forward calculation
85
method in determining the mineral assemblages, mineral modes and chemical
4
86
compositions of the minerals involved at different P–T conditions, based on the
87
assumption of closed chemical system during the metamorphic process.
88
A number of investigations on the metamorphic P–T paths and geochronology
89
of the metamorphic terranes distributed within the Palaeoproterozoic Trans-North
90
China Orogen (TNCO) (Zhao et al., 1998, 2000a, 2001a, 2005, 2012) have been
91
carried out in the last two decades (e.g., Zhai et al., 1993; Mei, 1994; Liu, 1996, 1997;
92
Guo et al., 1998, 2002, 2005; Wang et al., 1991; Zhao et al., 1999, 2000b, 2001b,
93
2002, 2007, 2010b; Liu et al., 2004, 2006, 2007; Kröner et al., 2005, 2006; O’Brien et
94
al., 2005; Faure et al., 2007; Trap et al., 2007, 2008, 2009a; Xiao et al., 2011; Lu et al.,
95
2013, 2014; Qian et al., 2013, 2015, 2016; Wang et al., 2014; Chen et al., 2015). Most
96
of these metamorphic terranes recorded clockwise P–T paths involving nearly ITD
97
segments, which were generally interpreted as the results of the subduction and
98
collision between the Eastern Block and the Western Block along the N–S-striking
99
TNCO at ~1.85 Ga (Fig. 1a) (Zhao et al., 1998, 2005, 2012).
100
The Taihua metamorphic complex, exposing in the southernmost margin of the
101
TNCO, experienced high-amphibolite- to granulite-facies metamorphism (Kang et al.,
102
1988; Qi, 1991, 1992; Chen et al., 1997; Zhou et al., 1997, 1998; Wang et al., 2014)
103
and provides a perfect window to explore the tectonothermal evolution of the TNCO.
104
Researches on metamorphism were carried out on amphibolites from the Taihua
105
complex (Jiang et al., 2011; Lu et al., 2013, 2014; Wang et al., 2014; Chen et al.,
106
2015), however, no metamorphic evolution of pelitic granulite has been studied by
107
now, which restricts our whole understanding on the tectonothermal evolution of the
5
108
southern margin of the TNCO in the Paleoproterozoic. This is because pelitic graulites
109
are usually deemed as markers for recognizing Precambrian subduction/collision belts,
110
on account of that the sedimentary protoliths of pelitic granulites could only be
111
brought down to the middle/lower crustal levels and experienced granulite-facies
112
metamorphism by subduction/collison process (Zhao and Zhai, 2013). In this paper,
113
we present detailed petrology, mineral chemistry and P–T conditions of
114
metamorphism estimated by both conventional thermobarometry and pseudosection
115
modeling for the pelitic granulites, collected from the Taihua Group in the Mts.
116
Huashan terrane, and reconstruct the P–T paths of these rocks to reveal the
117
tectonothermal history of the southernmost terminal of the TNCO in the
118
Paleoproterozoic.
119
2. Regional setting
120
The Taihua metamorphic complex, termed as the Taihua Group in the traditional
121
Chinese literature, is located in the southernmost margin of the TNCO. It is mainly
122
consisting of the Mts. Huashan terrane in the northwest, the Xiaoshan and Luoning
123
terranes in the middle and the Lushan and Wugang terranes in the southeast. In the
124
last few years, some studies were carried out on the geochronology and metamorphic
125
evolution of these terranes (e.g. Wan et al., 2006;Liu et al., 2009; Diwu et al., 2010,
126
2014; Huang et al., 2010, 2012, 2013; Lu et al., 2013, 2014; Wang et al., 2012, 2013,
127
2014; Chen et al., 2015). In the Luoning terrane, Jiang et al. (2011) and Chen et al.
128
(2015) proposed that the amphibolites, whose protolith age was 2.34–2.30 Ga,
129
recorded clockwise P–T paths containing isothermal decompression (ITD) segments,
6
130
and the metamorphism occurred during 1.97–1.94 Ga according to SIMS and
131
LA-ICP-MS U–Pb dating of metamorphic zircons. Additionally, Huang et al. (2012)
132
reported two magmatic events (2.32–2.30 Ga and 2.19–2.07 Ga) of the TTG gneisses
133
in this area. Chen et al. (2016) further found that four episodes of crustal growth and /
134
or reworking in this region have occurred at 2.85–2.72 Ga, 2.54–2.48 Ga, 2.35–2.30
135
Ga and 2.2–2.0 Ga, respectively, possibly to connect with the subduction–collision
136
between the Eastern and Western Blocks along the TNCO. In the Lushan and Wugang
137
terranes, the protolith ages of the TTG gneisses and amphibolites were recognized as
138
2.85–2.72 Ga (Liu et al., 2009; Diwu et al., 2010; Huang et al., 2010) followed by a
139
metamorphic age of 1.87–1.84 Ga (Wan et al., 2006;Yang,2008). Based on detailed
140
studies on the amphibolites from both blocks, Lu et al. (2013, 2014) proposed that
141
both of the Lushan and the Wugang terranes recorded clockwise P–T paths including
142
ITD segments and the upper amphibolite facies metamorphism occurred at ca.
143
1.95–1.86 Ga and 1.96–1.92 Ga, respectively.
144
Exposed on the northern and southern slopes of the Mts. Huashan in the
145
Shan’anxi and Henan Provinces (Fig. 1b), the Huashan metamorphic complex has
146
attracted many attentions in recent years. In summary, based on U–Pb dating of
147
zircons and
148
three obvious episodes of magmatism (~2.5 Ga, ~2.3 Ga and 1.87–1.80 Ga) and one
149
episode of metamorphism (1.80–1.96 Ga) were identified in this region (Wang et al.,
150
2012, 2013, 2014, 2016; Huang et al., 2013; Yu et al., 2013). Our previous studies on
151
petrology, mineral chemistry, geochronology and metamorphic P–T paths of the
40
Ar/39Ar dating of amphiboles from the Huashan metamorphic complex,
7
152
amphibolites from this region indicate that the Mts. Huashan metamorphic complex
153
experienced
154
Paleoproterozoic. Clockwise P–T paths involving ITD segments were retrieved from
155
these amphibolites (Wang et al., 2014), which probably imply that the
156
Paleoproterozoic collision occurred between the Eastern and Western Blocks of the
157
NCC along the TNCO.
high-amphibolite
to
granulite
facies
metamorphism
in
the
158
The garnet-bearing pelitic granulites were not found at the outcrop but were
159
collected from the mining sites, which were confirmed to belonging to the Taihua
160
complex by field observation. Sampling locations of these samples are shown in
161
Fig.1b. Petrography and metamorphic researches were performed on three
162
representative garnet-bearing pelitic granulite samples (S18, S25 and S37), and U–Pb
163
dating of metamorphic zircons were carried out on two samples (S7 and S18).
164
3. Petrography and metamorphic stages
165
Most of the pelitic granulites show retrograde “white-eye socket” texture (Fig.
166
2), which was originally named by Ma and Wang (1994) in mafic granulites to
167
explain the retrograde symplectic assemblages surrounding garnet porphyroblasts. On
168
the basis of micropetrographic observation, three stages of metamorphic mineral
169
assemblages were recognized in these granulites, designated as the prograde mineral
170
assemblages (M1), the peak mineral assemblages (M2) and the retrograde mineral
171
assemblages (M3), respectively. Detailed microstructures and reaction relationships
172
are described below. The symbols of minerals used in this study are after Whitney and
173
Evans (2010).
8
174
3.1 The prograde mineral assemblages (M1)
175
The prograde metamorphic mineral assemblages (M1) are preserved as mineral
176
inclusions within the garnet porphyroblasts (Fig. 2a–d), which are mainly composed
177
of biotite (Bt1) + plagioclase (Pl1) + quartz (Qz1) ± ilmenite (Ilm1). These
178
inclusion-type minerals are distributed randomly within the garnets, representing the
179
remnants of the prograde assemblages. It is noted that some inclusion-like minerals
180
distributed along the fractures within the garnets are not actually inclusion minerals,
181
but were formed within the garnet interiors during the retrograde metamorphic stage.
182
Only the inclusion minerals not cut by late fractures within the garnets and showing
183
no Fe–Mg re-exchange features with the surrounding garnet interiors are ascribed to
184
the prograde stage.
185
3.2 The metamorphic peak assemblages (M2)
186
The metamorphic peak mineral assemblages (M2) are represented by the
187
coarse-grained garnet porphyroblasts (Grt2) and matrix minerals biotite (Bt2),
188
orthopyroxene (Opx2), plagioclase (Pl2), quartz (Qz2), with minor K-feldspar (Kfs2),
189
ilmenite (Ilm2), zircon (Zr2) and magnetite (Mag2) (Fig. 2a–d). The straight contacts
190
and nearly homogeneous chemical compositions, described below, of these minerals
191
suggest that thermodynamic equilibrium had been approached during the
192
metamorphic peak stage. It is inferred that the metamorphic peak assemblages (M2)
193
were formed from the prograde assemblages (M1) possibly by the following reaction:
194 195
Bt1 + Pl1 ± Ilm1 → Grt2 +Bt2 + Opx2 + Pl2 + Kfs2 ± Mag2 ± Ilm2 (M1)
(M2) 9
196
3.3 The retrograde mineral assemblages (M3)
197
The retrograde metamorphic assemblages are characterized by the formation of
198
symplectic assemblages around the garnet porphyroblasts, resulted from the
199
decomposition reactions between the garnet rims and the neighboring minerals in the
200
matrix. Such kind of reaction textures, nicknamed as “white-eye socket” texture,
201
represent typical decompression and decomposition reactions in mafic granulites and
202
amphibolites within the Trans-North China Orogen (e.g., Wang et al., 1991; Liu, 1996;
203
Guo et al., 1998, 2002; Zhao et al., 2000b, 2001b, 2010a; O’Brien et al., 2005; Xiao et
204
al., 2011; Lu et al., 2013, 2014; Wang et al., 2014; Chen et al., 2015). The symplectic
205
mineral assemblages are mainly comprised of biotite (Bt3) + plagioclase (Pl3) + quartz
206
(Qz3) ± orthopyroxene (Opx3) around the embayed garnet porphyroblasts (Fig. 2a–d),
207
suggesting the following possible reaction:
208 209 210
Grt2 (rim) + Bt2 + Pl2 → Grt3 + Bt3 + Pl3 ± Opx3 (M2)
(M3)
4. Mineral chemistry
211
X-ray compositional mapping of the garnets (Fig. 3) as well as mineral chemical
212
compositions of the pelitic granulite samples S18, S25 and S37 were analyzed using
213
the JOEL JXA 8230 electron microprobe equipped at the School of Resources and
214
Environment Engineering, Hefei University of Technology, China. The analytical
215
conditions were 15 kV accelerating voltage, a beam current of 20 nA with an electron
216
beam size of 5 µm and 10–20 s counting time. Natural and synthetic minerals were
217
used as standards, and the program ZAF was used for matrix correction. For each kind 10
218
of mineral of any generation, at least three grains were analyzed and at least three spot
219
analyses were performed for each grain. Representative mean chemical compositions
220
of the minerals are presented in Tables 1–4. The detailed compositional features of the
221
minerals are described below.
222
4.1. Garnet
223
The bell-shaped XMn and Fe# [=Fe/(Fe+Mg)] zoning profiles of the garnet in
224
metapelites were interpreted as typical prograde growth zonation of metapelitic garnet
225
(Spear et al., 1990; Spear and Florence, 1992). Sometimes the bell-shaped profiles
226
could hardly be preserved in high-grade metamorphic rocks, if Fe-Mg re-exchange
227
occurred during slow cooling after the metamorphic peak, led to increase of Fe# value
228
in the garnet rim (Spear and Florence, 1992). Simultaneous increasing of the Fe# and
229
XMn values of the garnet rim suggests that the garnet rim experienced net transfer and
230
Fe-Mg re-exchange reactions, lead to formation of the symplectite (Kohn and Spear,
231
2000). The X-ray mapping analyses (Fig. 3a–c) of the garnet porphyroblasts show
232
homogeneous features with no or weak prograde profiles from the core to the mantle
233
domains and weak Fe-Mg re-exchange in the outer rims, which suggest that
234
thermodynamic equilibrium had possibly been achieved within the peak mineral
235
assemblages at the metamorphic peak stage and re-equilibrium occurred during the
236
retrograde stage. All the garnets are dominated by almandine (XAlm = 0.53–0.68),
237
pyrope (XPyr = 0.25–0.42) with minor grossular (XGrs = 0.01–0.11) and spessartine
238
(XSps = 0.02) components (Table 1). Consistent with the X-ray mapping analyses, the
239
rim-core-rim analytical chemical profiles of these garnets (Fig. 4a–c) also show no or
11
240
weak compositional zonation from the core to the mantle domains. Slight increases of
241
XAlm (from 0.53–0.63 to 0.60–0.68), Fe# (from 0.57–0.69 to 0.66–0.74) and a weak
242
increase of XGrs (from 0.02–0.11 to 0.01–0.08) were observed towards the rims (Fig.
243
4a–c), indicating re-equilibrium occurred during the retrograde metamorphic stage.
244
No obvious increase of spessartine component corresponding to the breakdown of
245
garnet rims (Kohn and Spear, 2000) was observed, probably because of their low
246
spessartine contents (XSps = 0.02).
247
4.2. Orthopyroxene
248
Orthopyroxene is subhedral or anhedral, with variable grain size in the matrix
249
(Opx2) or occurs as intergrowth mineral with the matrix biotite. Symplectic
250
orthopyroxene (Opx3) is only observed in sample S25. The matrix orthopyroxene
251
(Opx2) is richer in FeO (24.47–29.20 wt%) and poorer in MgO (17.44–20.41 wt%)
252
components with XMg [=Mg/(Fe+Mg)] values varying between 0.52–0.61. The
253
symplectic orthopyroxene (Opx3) has lower FeO (23.09 wt%) and higher MgO (21.15
254
wt%) contents with XMg = 0.63 (Table 2).
255
4.3. Biotite
256
Three textural types of biotite were analyzed in the pelitic granulites: the
257
inclusion-type biotite (Bt1) within the garnet porphyroblast, matrix-type biotite (Bt2)
258
intergrown with orthopyroxene in the matrix and retrograde biotite (Bt3) intergrown
259
with plagioclase and quartz in the symplectite. These three types of biotite display
260
slight differences in FeO and TiO2 components (Table 3). The Bt1 has FeO contents of
261
10.00–17.88 wt% and TiO2 contents of 2.03–4.41 wt%. In samples S18 and S37, the
12
262
Bt2 have lower FeO contents (14.46–17.39 wt%) and higher TiO2 contents (3.76–4.43
263
wt%) than those of Bt1. In sample S25, the Bt2 has higher FeO contents (13.80 wt%)
264
and lower TiO2 contents (4.09 wt%) than those of Bt1. In all these samples, the Bt3 is
265
richer in FeO (15.35–17.85 wt%) and poorer in TiO2 (3.47–4.46 wt%) contents than
266
those of the Bt2.
267
4.4. Plagioclase
268
Representative chemical compositions of three types of plagioclase are
269
summarized in Table 4: the inclusion-type plagioclase (Pl1) within the garnet
270
porphyroblast, plagioclase in the matrix (Pl2) and retrograde plagioclase (Pl3) formed
271
coeval to symplectic biotite and quartz. Most of the plagioclase grains are chemically
272
homogeneous, but chemical diversities exist for different plagioclase crystals either
273
among different samples or in the different assemblages formed at different
274
metamorphic stages within one sample.
275
In sample S18, the Pl2 and Pl3 contain similar anorthite contents (An = 29), but
276
lower than that of the Pl1 (An = 36). In sample S25, the anorthite contents in Pl1 (An =
277
16) and Pl2 (An = 16) are slightly lower than the Pl3 (An = 17). In sample S37, the
278
anorthite content increases from the Pl1 (An = 34) to the Pl2 (An = 55). The Pl3 has the
279
highest anorthite content (An = 58). The increases of anorthite contents from Pl2 to Pl3
280
in S25 and S37 suggest that the breakdown of garnet rims supplied additional CaO
281
content to the newly formed Pl3 during the retrograde stage.
282
5. Metamorphic P–T conditions
283
5.1. Geothermobarometry 13
284
Present available geothermometers and geobarometers were employed to
285
determine the P–T conditions of the Huashan pelitic granulites. However, there are no
286
suitable geobarometers for the prograde mineral assemblages (Bt1 + Pl1 + Qz1 ± Ilm1).
287
The Ti-in-biotite geothermometer for TiO2-saturated metapelites proposed by Wu and
288
Chen (2015) is appropriate with a random error of ca. ±65 °C. However, only
289
inclusion-type biotite (Bt1) in S37 contains suitable XTi (0.11), which is located in the
290
compositional limits of biotite (XTi = 0.02–0.14) for this geothemometer. A
291
temperature of 520–530 °C was determined by this geothemometer at a given pressure
292
of 4–6 kbar. The metamorphic peak and retrograde P–T conditions of these pelitic
293
granulites were determined by applying the garnet–biotite (GB) geothermometer
294
(Holdaway, 2000) combined with the garnet–biotite–plagioclase–quartz (GBPQ)
295
geobarometer (Wu et al., 2004) and the garnet–orthopyroxene–plagioclase–quartz
296
(GOPQ) geothermobarometer (Lal et al., 1993). It is noteworthy that Fe-Mg
297
re-exchanging during cooling after the metamorphic peak might occur between the
298
matrix-type ferromagnesian minerals, especially for the contacting biotite,
299
orthopyroxene and garnet. Therefore, the compositions of isolated garnet, biotite and
300
orthopyroxene were employed to calculate the peak P–T conditions. It is noted that
301
although retrograde zonings were observed on the garnet rims, thermodynamic
302
equilibrium might not have been achieved between the garnet rims and the symplectic
303
minerals (Wu et al., 2014). Therefore, accuracy of the retrograde P–T conditions
304
obtained here need to be used with caution.
305
The computed P–T conditions of the three metamorphic stages of the pelitic
14
306
granulites are listed in Table 5.
307
5.1.1 Sample S18
308
The metamorphic peak (M2) P–T conditions were estimated to be 7.2
309
kbar/730 °C by the GB geothermometer coupled with the GBPQ geobarometer.
310
Similar peak (M2) P–T conditions of 6.8 kbar/760 °C were obtained by the GOPQ
311
geothermobarometers. The retrograde assemblages (M3) recorded P–T conditions of
312
5.1 kbar/680 °C determined by GB geothermometer coupled with the GBPQ
313
geobarometer. Therefore, a clockwise P–T path was retrieved (Fig. 5a).
314
5.1.2 Sample S25
315
The M2 P–T conditions of this sample were determined to be 7.0 kbar/730 °C by
316
GB geothermometer combined with GBPQ geobarometer or 6.8 kbar/760 °C obtained
317
by the GOPQ geothermobarometers, respectively. The M3 assemblages recorded P–T
318
conditions of 4.2 kbar/680 °C determined by the GB geothermometer coupled with
319
the
320
geothermobarometers, respectively. Although the grossularite content of garnet (Xgrs
321
= 1–2%) and anorthite content of plagioclase (An = 16–17) in these two metamorphic
322
stages were lower than the recommended lower limits (Xgrs > 3%, An > 17) for the
323
GBPQ geobarometer as given in Wu et al. (2004), it still gave similar results
324
compared with the results obtained by the GOPQ geothermobarometers. Therefore, a
325
clockwise P–T path was also reconstructed (Fig. 5b).
326
5.1.3 Sample S37
327
GBPQ
geobarometer
or
4.1
kbar/570
°C
obtained
by the
GOPQ
The M2 P–T conditions were calculated as 8.6 kbar/740 °C by the GB
15
328
geothermometer coupled with the GBPQ geobarometer or 7.3 kbar/810 °C by the
329
GOPQ geothermobarometers. The M3 P–T conditions were estimated as 6.4
330
kbar/740 °C by the GB geothermometer in concert with the GBPQ geobarometer. A
331
clockwise P–T path was also reconstructed (Fig. 5c).
332
5.2. Pseudosection modeling
333
Sometimes people may make mistakes in distinguishing different mineral
334
assemblages formed at different metamorphic stages in medium to high grade
335
metamorphic rocks (e.g., Nicollet and Goncalves, 2005; Vernon et al., 2008), which
336
may result in wrong conclusions for the regional tectonic evolution. In addition,
337
thermodynamic equilibrium might not have been achieved between the garnet rims
338
and the symplectic minerals (Wu et al., 2014). To confirm the P–T conditions
339
obtained by conventional geothermobarometers, we performed a P–T pseudosection
340
on sample S18 with the Perple_X computer program (Connolly, 2005).
341
5.2.1 P–T pseudosection modeling
342
The P–T pseudosection was calculated with the Perple_X computer program
343
package (Connolly, 2005; Version of 6.68) using the internally consistent
344
thermodynamic dataset of Holland and Powell (1998, updated 2002). The bulk-rock
345
composition of the chosen sample was analyzed by X-ray fluorescence spectrometry
346
(XRF) at the Institute of Geology and Geophysics, Chinese Academy of Sciences,
347
Beijing. The above studies on petrography and mineral chemistry suggest that the
348
amounts of Mn and Fe3+ cations in the minerals are negligible; therefore the MnO and
349
Fe2O3 contents were ignored in the pseudosection calculation. On the contrary, the
16
350
noticeable Ti amount in biotite demonstrates that the TiO2 amount in bulk-rock
351
composition could affect the stable region of biotite in pseudosection constructions in
352
metapelite (Peterson et al., 1991; Dooley et al., 1996). So the P–T pseudosection was
353
calculated
354
(NCKFMASHT) system. Apatite is present in this sample, which contains most of the
355
P2O5 contents in the bulk-rock composition. So we deducted the CaO content,
356
constituent of apatite, from the bulk-rock composition according to the standard
357
molecular formula of apatite (Ca: P = 5:3, in mol). As we know, there is a great
358
variety in the FeO/Fe2O3 ratio among metapelites. Due to the high Fe3+ contents in the
359
garnet porphyroblast and the presence of magnetite in the matrix mineral assemblages,
360
83% of total Fe2O3 (Fe2O3T) is assumed to be the FeO, which means a reasonable high
361
Fe2O3 content of total Fe2O3 content of the rock. Besides, the loss on ignition (LOI)
362
was employed as the H2O content. With these reasonable assumptions, the final
363
effective bulk-rock composition of the sample (in wt%) is as follows: SiO2 = 52.64,
364
TiO2 = 0.85, Al2O3 = 17.69, FeO = 9.93, MgO = 5.87, CaO = 3.15, Na2O = 3.94, K2O
365
= 2.38 and H2O = 0.56.
in
the
Na2O–CaO–K2O–FeO–MgO–Al2O3–SiO2–H2O–TiO2
366
The minerals involved in the pseudosection construction include: garnet (Grt),
367
plagioclase (Pl), orthopyroxene (Opx), biotite (Bt), cordierite (Crd), K-feldspar (Kfs),
368
ilmenite
369
activity-composition (a-X) models used in the pseudosection calculation are those of
370
garnet (White et al., 2007), plagioclase (Newton et al., 1980), orthopyroxene (Holland
371
and Powell, 1998), biotite (Tajcmanová et al., 2009), cordierite (Holland and Powell,
(Ilm),
rutile
(Rt),
quartz
(Qz)
17
and
silicate
melt
(Liq).
The
372
1998), K-feldspar (Waldbaum and Thompson, 1968), ilmenite (White et al., 2000)
373
and melt (White et al., 2007). Rutile and quartz are essentially pure end-member
374
phases.
375
5.2.2 P–T pseudosection
376
The P–T pseudosection computed in the P–T range of 2–10 kbar/500–1000 °C in
377
the NCKFMASHT system for the pelitic granulite (S18) is shown in Fig. 6. Biotite,
378
orthopyroxene, plagioclase and K-feldspar are stable and are present in most of the
379
pseudosection regions. Garnet is a stable phase in high pressure fields with the
380
garnet-in line starting from 3 kbar/500 °C to 8.5 kbar/1000 °C. Quartz appears in most
381
fields with the quartz-out line vertically lying from 800 °C at 2 kbar to 920 °C at 10
382
kbar. Cordierite is stable only in low pressure fields (<4 kbar), and rutile is stable in
383
high pressure and low temperature fields (P>7 kbar, T<560 °C). The solidus curve
384
vertically lies from 790 °C at 2 kbar to 890 °C at 10 kbar, which is consistent with no
385
partial melting in this rock (i.e., it was a closed system).
386
It’s also difficult to estimate the prograde P–T conditions in the pseudosection
387
because no prograde chemical profiles were preserved in garnet porphyroblasts.
388
However, there must be a prograde stage for metapelite because the mud was brought
389
down to the middle/lower crustal levels and experienced granulite-facies
390
metamorphism.
391
The homogeneous chemical composition of the garnet porphyroblast from the
392
core to the mantle in sample S18, formed during the metamorphic peak stage, was
393
normalized as XAlm = 0.65, XPyr = 0.29 and Xgrs = 0.06 after removing the XSps
18
394
content. The isopleths of XAlm (ranging from 0.65 to 0.70), XPyr (ranging from 0.25 to
395
0.29) and Xgrs (ranging from 0.05 to 0.06) in garnet were shown in the P–T
396
pseudosection (Fig. 6). The P–T conditions of the metamorphic peak was constrained
397
as 7.8 kbar/810 °C by pseudosection, which is a little higher than the results of
398
6.8–7.2 kbar/730–760 °C estimated by conventional geothermobarometers. This is
399
probably due to the effect of Fe-Mg diffusion between ferromagnesian minerals after
400
the metamorphic peak stage, although the compositions of isolated garnet, biotite and
401
orthopyroxene were employed to calculate the peak P–T conditions. The
402
corresponding peak mineral assemblage is Opx + Grt + Pl + Bt + Kfs + Qz, which
403
agrees with the peak mineral assemblage we observed under microscope. Therefore, a
404
prograde reaction (dashed line in Fig. 6) from Opx + Grt + Pl + Bt + Kfs + Ilm + Qz
405
(M1) to Opx + Grt + Pl + Bt + Kfs + Qz (M2) was inferred. No Opx and Kfs were
406
observed in the inclusion-type mineral assemblages (M1, Bt + Pl + Ilm + Qz) in this
407
sample, probably suggests that no Opx and Kfs survived as inclusions in the garnet
408
during the prograde stage.
409
Analogously, composition of the garnet rim was normalized as XAlm = 0.70, XPyr
410
= 0.25 and Xgrs = 0.05 according to EPMA data. The corresponding isopleths
411
constrain the retrograde (M3) P–T conditions to be 5.0 kbar/630 °C (Fig. 6), which
412
was also similar to those (5.0 kbar/680 °C) estimated by conventional
413
geothermobarometers. So a clockwise P–T path was also obtained for the pelitic
414
granulite in the P–T pseudosection modeling.
415
5.3. Metamorphic P–T paths 19
416
The metamorphic P–T conditions of the M1, M2 and M3 assemblages were
417
estimated by both conventional geothermobarometers and P–T pseudosection
418
modeling. The prograde (M1) metamorphic P–T conditions were proposed as
419
520–530 °C/4–6 kbar (assumed). The metamorphic peak (M2) P–T conditions were
420
determined as 6.8–8.6 kbar/730–810 °C, belonging to the transition zone of high
421
amphibolite to granulite facies and intermediate P/T metamorphic facies series
422
(Miyashiro, 1961; Spear, 1993, pp. 15–22). The retrograde (M3) P–T conditions were
423
estimated as 4.1–6.4 kbar/570–740 °C. Therefore, clockwise P–T paths were
424
constructed for these pelitic granulite samples.
425
6. Geochronology
426
6.1. Analytical methods
427
Zircon grains collected from Samples S7 and S18 were mounted in epoxy
428
mounts with zircon standard Plešovice (Sláma et al., 2008) and Qinghu (Li et al.,
429
2009), which were then polished to section the crystals in half for analyses. All the
430
zircons were taken micrographs of reflected and transmitted light as well as
431
cathodoluminescence (CL) images to reveal their internal structures. The mount was
432
then vacuum-coated with high-purity gold prior to secondary ion mass spectrometry
433
(SIMS) analysis. Analyses of U, Th and Pb were performed using the Cameca
434
IMS-1280 SIMS mass spectrometer equipped at the Institute of Geology and
435
Geophysics, Chinese Academy of Sciences, Beijing. Detailed analytical procedures
436
were described by Li et al. (2009). The analytical spot was an ellipsoid with size of
437
about 30µm×20µm. Non-radiogenic 204Pb was used to correct measured compositions
20
438
for common Pb. The average of present-day crustal composition (Stacey and Kramers,
439
1975) was used for the common Pb assuming that the common Pb is largely surface
440
contamination introduced during the preparation of samples. The analytical results are
441
listed in Table 6. The uncertainties on individual analyses are reported at the 1σ level
442
and the mean ages for U/Pb (Pb/Pb) analyses are quoted with the 95% confidence
443
interval. Data reduction was carried out using the Isoplot/Ex v. 3.75 program (Ludwig,
444
2003).
445
6.2. Analytical results
446
Zircon grains from sample S7 are stubby columnar and round in shape and about
447
100–200 µm in length. Most of the zircons show homogeneous texture with low
448
luminescence in cathodoluminescence (CL) images (Fig. 7a) displaying features of
449
possible metamorphic origin. Some round grains show cores with weak magmatic
450
rhythmic textures, which are considered as detrital zircons. Twenty-eight U–Pb spot
451
analyses were obtained from 22 zircon grains. The U and Th contents and the U/Th
452
ratios of the 23 valid analytical spots performed on the metamorphic zircon grains are
453
in the range of 149–3003 ppm, 5–195 ppm and 0.02–0.1, respectively. All these
454
analytical spots are distributed on or close to the concordia and yield an upper
455
intercept age of 1824±13 Ma, which is considered as the age of metamorphism, with a
456
similar weighted mean 207Pb/206Pb age of 1846±6 Ma (Fig. 8a). The rest spot analyses
457
performed on the detrital zircons are distributed on or close to the concordia, and the
458
207
459
of the detrital zircons.
Pb/206Pb ages range from 2001 Ma to 2255 Ma, interpreted to be the formation age
21
460
In sample S18, zircon grains are also stubby columnar and round in shape and
461
about 100–200 µm in length. Some zircons show homogeneous texture with low
462
luminescence in cathodoluminescence (CL) images (Fig. 7b) implying possible origin
463
of metamorphism. Some zircons show core-rim structures in CL images (Fig. 7b). The
464
cores display oscillatory zonings, indicative of magmatic origin. Around the cores are
465
homogeneous rims with higher luminescence, indicative of possible metamorphic
466
origin. Twenty-three spot analyses were conducted on twenty zircon grains. The U,
467
Th contents and the Th/U ratios of the fourteen valid analytical spots on the zircon
468
rims or metamorphic grains are in the range of 13–124 ppm, 5–19 ppm and 0.08–0.36,
469
respectively. All of these analytical spots define a linear array on the concordia
470
diagram and yield an upper intercept age of 1818±22 Ma, possibly reflecting the age
471
of the metamorphic event, with a similar weighted mean
472
Ma (Fig. 8b). The rest eight valid spots analyzed on the magmatic cores also define a
473
linear array on the concordia diagram, yielding an upper intercept age of 2547±47 Ma,
474
possibly reflecting an age of one magmatic event; and a lower intercept age of
475
1792±310 Ma, which is close to the age of metamorphism (Fig. 8b).
476
7. Discussion
207
Pb/206Pb age of 1823±8
477
The North China Craton (NCC) is one of the oldest and largest cratons in the
478
world (as old as ~3.8 Ga; Liu et al., 1992) with widespread Archean to
479
Paleoproterozoic basement, albeit whose Precambrian crustal history is hotly debated.
480
A number of tectonic subdivision models have been proposed for the formation and
481
evolution of the basement of the NCC (eg., Wu et al., 1998; Zhao et al., 1998, 2000a,
22
482
2001a, 2005, 2012; Zhai et al., 2000, 2005, 2010; Kusky and Li, 2003; Santosh et al.,
483
2006; Faure et al., 2007; Trap et al., 2007, 2012; Zhai and Peng, 2007; Santosh, 2010;
484
Kusky, 2011; Zhai and Santosh, 2011; Peng et al., 2014). A broad consensus among
485
these diverse models is that there is a S–N-trending Paleoproterozoic tectonic belt in
486
the central part of the NCC, named either the Trans-North China Orogen (TNCO;
487
Zhao et al., 2001a, 2005), or the Central Orogenic Belt (Kusky and Li, 2003; Santosh,
488
2010; Kusky, 2011) or the Jinyu Orogenic Belt (Zhai and Peng, 2007) or the Fuping
489
Block (Faure et al., 2007; Trap et al., 2007, 2012), although there still remains
490
controversial about the boundaries of these belts. Another familiar debate focuses on
491
the formation timing of these belts, which were involved in the final amalgamation of
492
the NCC. For example, some researches believe that the final amalgamation of the
493
NCC occurred at ~1.85 Ga by continent-continent collision along the TNCO between
494
the Eastern and Western Blocks (e.g., Zhao et al., 1998, 2000a, 2012; Guo et al., 2005;
495
Kröner et al., 2005), whereas others argue that the collision between the Eastern and
496
Western Blocks occurred at ~2.5 Ga along the Central Orogenic Belt (Kusky and Li,
497
2003; Kusky, 2011). Moreover, some other different models are also presented (e.g.,
498
Faure et al., 2007; Trap et al., 2007, 2012; Zhai and Peng, 2007; Santosh, 2010; Zhai
499
et al., 2010). In the last two decades, from the north to the south, numerous
500
investigations have revealed that the metamorphic complexes in the TNCO all record
501
clockwise P–T paths with retrograde isothermal decompression (ITD) process, such as
502
the Huai’an complex (Zhai et al., 1993; Liu, 1997; Guo et al., 1998, 2002, 2005; Zhao
503
et al., 2008), the Hengshan complex (Wang et al., 1991; Guo et al., 1999; Zhao et al.,
23
504
2001b; Qian et al., 2015, 2016), the Wutai complex (Wang et al., 1996; Zhao et al.,
505
1999; Yu et al., 2001; Qian et al., 2013, 2016), the Fuping complex (Liu, 1996; Zhao
506
et al., 2000b), the Lüliang complex (Trap et al., 2009b; Zhao et al., 2010b), the
507
Zanhuang complex (Xiao et al., 2011), the Zuoquan complex (Xiao et al., 2014) and
508
the Taihua complex (Jiang et al., 2011; Lu et al., 2013, 2014; Wang et al., 2014; Chen
509
et al., 2015), which make it much more clear that the whole TNCO was involved in
510
the subduction- and collision- related processes during the amalgamation of the
511
Eastern and Western Blocks in the Paleoproterozoic, as suggested by Zhao et al.
512
(2001, 2005, 2012).
513
In this paper, it is found that the pelitic granulite from the Huashan complex
514
underwent similar tectonothermal processes. Clockwise P–T paths were reconstructed
515
for these pelitic granulite samples, also imply initial crustal thickening followed by
516
possible rapid exhumation. This is consistent with a subduction and then
517
continent-continent collision environment (England and Thompson, 1984; Bohlen,
518
1991; Lu, 1991). Fortunately, garnet-bearing amphibolites widely distribute in the
519
Taihua metamorphic complex, which record clockwise P–T paths with ITD segments,
520
indicating an initial crustal thickening followed by rapid exhumation/uplift.
521
Metamorphic evolution of the intercalated metapelitic granulites and amphibolites of
522
the Taihua complex, all suggest that the southern segment of the TNCO was also
523
involved in the amalgamation of the Eastern and Western Blocks in the
524
Paleoproterozoic.
24
525
It is widely accepted that the final amalgamation of the Eastern and Western
526
Blocks occurred at ~1.85 Ga (Zhao et al., 1998, 2000a, 2005), which was
527
demonstrated by the metamorphic ages obtained from the northern and middle
528
segments of the TNCO (e.g., Mao et al., 1999; Guo and Zhai, 2001; Zhao et al., 2002,
529
2008a,b, 2010a,b; Liu et al., 2004, 2007; Guo et al., 2005; Kröner et al., 2005, 2006;
530
Faure et al., 2007; Trap et al., 2007, 2008, 2012; Xiao et al., 2011, 2013). In recent
531
years, more and more older metamorphic ages were found from the metamorphic
532
complexes in the whole TNCO, such as 1.97–1.92 Ga from the Taihua complex (Jiang
533
et al., 2011; Wang et al., 2012, 2013, 2014; Lu et al., 2013, 2014, 2015; Diwu et al.,
534
2014; Chen et al., 2015), 1.95–1.91 Ga from the Lüliang complex (Liu et al., 2006;
535
Trap et al., 2009b), ~1.95 Ga from the Wutai complex (Qian et al., 2013), 1.96 Ga and
536
1.92 Ga from the Hengshan complex (Qian et al., 2015, 2016) and 1.95 Ga from the
537
Chengde complex (Qu et al., 2012). The widespread metamorphic ages of 1.97–1.80
538
Ga in the whole TNCO possibly indicate that the tectonothermal evolution of the
539
TNCO might be a long and complex process, which possibly started as early as ~1.97
540
Ga and lasted as late as 1.80 Ga (Chen et al., 2015).
541
Another controversy is about the polarity of the Neoarchean to Paleoproterozoic
542
subduction operated in the Tran-North China Orogen (Zhao and Zhai, 2013), mainly
543
including the eastward subduction model (Zhao et al., 2001a, 2005; Zhang et al., 2007,
544
2009, 2012) and the westward subduction model (e.g., Faure, et al., 2007; Trap et al.,
545
2007; Zhu and Zheng, 2009; Santosh, 2010; Wang et al., 2010; Kusky, 2011). The
546
metamorphic ages obtained from the Taihua complex was summarized in Table 7. We
25
547
can clearly conclude that the metamorphic ages of the Huashan complex in the west
548
(mostly≤1.90 Ga) are obviously younger than those of the Luoning, Lushan and
549
Wugang terranes in the east (mostly ≥1.90 Ga). This phenomenon possibly implies
550
that the tectonothermal event in the southern segment of the TNCO possibly started
551
from the east, and then extended to the west, which could be well explained by the
552
eastward-directed subduction model for the TNCO (Zhao et al., 2001a, 2005; Zhang
553
et al., 2007, 2009, 2012). Furthermore, the metamorphic P–T conditions of the
554
metamorphic peak show a gradually increasing trend in the pressure from the
555
Huashan terrane in the west (6.7–8.6 kbar/700–820 °C, Wang et al., 2014; this study)
556
to the Luoning, Lushan and Wugang terranes in the east (8.9–10.8 kbar/710–820 °C,
557
Lu et al., 2013, 2014; Chen et al., 2015). The existing of thermal relaxation in regions
558
where the crust is rapidly thickened (e.g., Richardson and England, 1979; England
559
and Thompson, 1984) tells us that the mineral reactions in metamorphic rocks are
560
more sensitive to the changes in pressure than in temperature. The obvious higher
561
pressure recorded in the east regions possibly implies a deeper subduction or more
562
degrees of crustal thickening occurred in the east, which also supports the
563
eastward-directed subduction model for the TNCO (Zhao et al., 2001a, 2005; Zhang
564
et al., 2007, 2009, 2012).
565
8. Conclusions
566
(1) Three generations of mineral assemblages have been identified in the pelitic
567
granulites from the Huashan terrane, Taihua metamorphic complex, southern
568
Trans-North China Orogen. Clockwise P–T paths were reconstructed by both
26
569
conventional thermobarometry and pseudosection modeling, which pass from 4–5
570
kbar/520–530 °C through 6.8–8.6 kbar/730–810 °C to 4.1–6.4 kbar/570–740 °C, and
571
suggest that the Huashan terrane was involved in the subduction/collision process
572
between the Eastern and Western Blocks along the Trans-North China Orogen.
573
(2) SIMS U–Pb dating of metamorphic zircons yielded metamorphic ages of
574
1823–1846 Ma. Combined with geochronological data from the literature, it is
575
concluded that the tectonothermal evolution of the Trans-North China Orogen could
576
be a long and complex process, which started as early as ~1.97 Ga and lasted as late
577
as 1.80 Ga.
578
(3) The older metamorphic ages and higher metamorphic peak pressures
579
preserved in the east region than those in the west of the Taihua complex suggest the
580
possible eastward-directed subduction model of the TNCO.
581 582
Acknowledgements
583
Professor Yong-Hong Shi and Miss Juan Wang are specially thanked for helping
584
the authors in electronic microprobe analyses. Xin Zhou and Xiao-Qiang Yang are
585
also thanked for their discussions and suggestions. The quality of the original
586
manuscript has been improved through reviews by two anonymous referees. This
587
work was supported by the National Natural Science Foundation of China (41225007,
588
40872125, 41130314).
589 590
References 27
591 592 593 594 595 596
Bohlen, S.R., 1987. Pressure–temperature–time paths and a tectonic model for the evolution of granulites. Journal of Geology 95, 617–632. Bohlen, S.R., 1991. On the formation of granulites. Journal of Metamorphic Geology 9, 223–229. Brown, M., 1993. P–T–t evolution of orogenic belts and the causes of regional metamorphism. Journal of the Geological Society 150, 227–241.
597
Brown, M., 2009. Metamorphic patterns in orogenic systems and the geological
598
record. Journal of the Geological Society, London, Special Publications 318,
599
37–74.
600
Chen, H.X., Wang, J., Wang, H., Wang, G.D., Peng, T., Shi, Y.H., Zhang, Q., Wu,
601
C.M., 2015. Metamorphism and geochronology of the Luoning metamorphic
602
terrane, southern terminal of the Palaeoproterozoic Trans-North China Orogen,
603
North China Craton. Precambrian Research 264, 156–178.
604
Chen HX, Wang HYC, Peng T and Wu CM (2016) Petrogenesis and geochronology
605
of the Neoarchean-Paleoproterozoic granitoid and monzonitic gneisses in the
606
Taihua complex: Episodic magmatism of the southwestern Trans-North China
607
Orogen. Precambrian Research, 287: 31–47.
608
Chen, L.G., Wang, B.Y., Xue, Y.Z., 1997. The re-establishment of Taihua Group in
609
Xiao Qinling, Shanxi. Geology of Shanxi 15, 20–30 (in Chinese with English
610
abstract).
611
Connolly, J.A.D., 2005. Computation of phase equilibria by linear programming: a
612
tool for geodynamic modeling and its application to subduction zone
28
613
decarbonation. Earth and Planetary Science Letters 236, 524–541.
614
Diwu, C.R., Sun, Y., Lin, C.L., Wang, H.L., 2010. LA–(MC)–ICPMS U–Pb zircon
615
geochronology and Lu–Hf isotope compositions of the Taihua Complex on the
616
southern margin of the North China Craton. Chinese Science Bulletin 55,
617
2557–2571.
618
Diwu, C.R., Sun, Y., Zhao, Y., Lai, S.C., 2014. Early Paleoproterozoic (2.45–2.20 Ga)
619
magmatic activity during the period of global magmatic shutdown: Implications
620
for the crustal evolution of the southern North China Craton. Precambrian
621
Research 255, 627–640.
622 623
Dooley, D.F., Patiño, Douce, A.E., 1996. Fluid-absent melting of F-rich phlogopite + rutile + quartz. American Mineralogist, 1996, 81, 202–212.
624
Droop, G.T.R., 1987. A general equation for estimating Fe3+ concentrations in
625
ferromagnesian silicates and oxides from microprobe analyses, using
626
stoichiometric criteria. Mineralogical Magazine 51, 431–435.
627
England, P.C., Richardson, S.W., 1977. The influence of erosion upon the mineral
628
facies of rocks from different metamorphic environments. Journal of the
629
Geological Society 134, 201–213.
630
England, P.C., Thompson, A.B., 1984. Pressure–temperature–time paths of regional
631
metamorphism I. Heat transfer during the evolution of regions of thickened
632
continental crust. Journal of Petrology 25, 894–928.
633
Faure, M., Trap, P., Lin, W., Monié, P., Bruguier, O., 2007. Polyorogenic evolution of
634
the Paleoproterozoic Trans-North China Belt, new insights from the
29
635
Lüliangshan–Hengshan–Wutaishan and Fuping massifs. Episodes 30, 1–12.
636
Guo, J.H., O’Brien, P.J., Zhai, M.G., 2002. High-pressure granulites in the Sanggan
637
area, North China Craton: Metamorphic evolution, P–T paths and geotectonic
638
significance. Journal of Metamorphic Geology 20, 741–756.
639
Guo, J.H., Sun, M., Chen, F.K., Zhai, M.G., 2005. Sm–Nd and SHRIMP U–Pb zircon
640
geochronology of high-pressure granulites in the Sanggan area, North China
641
Craton: Timing of Paleoproterozoic continental collision. Journal of Asian Earth
642
Sciences 24, 629–642.
643
Guo, J.H., Zhai, M.G., 2001. Sm–Nd age dating of high-pressure granulites and
644
amphibolite from Sanggan area, North China craton. Chinese Science Bulletin
645
46, 106–111.
646
Guo, J.H., Zhai, M.G., Li, Y.G., Li, J.H., 1999. Metamorphism, P–T paths and
647
tectonic significance of garnet amphibolite and granulite from Hengshan, North
648
China Craton. Scientia Geologica Sinica 34, 311–325 (in Chinese with English
649
abstract).
650
Guo, J.H., Zhai, M.G., Li, Y.G., Yan, Y.H., 1998. Contrasting metamorphic P–T
651
paths of Archaean high pressure granulites from the North China Craton:
652
metamorphism and tectonic significance. Acta Petrologica Sinica 14, 430–448
653
(in Chinese with English abstract).
654 655 656
Harley, S.L., 1989. The origins of granulites, a metamorphic perspective. Geological Magazine 126, 215–247. Holdaway, M.J., 2000. Application of new experimental and garnet Margules data to
30
657
the garnet–biotite geothermometer. American Mineralogist 85, 881–892.
658
Holdaway, M.J., Mukhopadhyay, B., 1993. A re-evaluation of the stability relations of
659
andalusite: thermochemical data and phase diagram for the aluminum silicates.
660
American Mineralogist 78, 298–315.
661 662
Holland, T.J.B., Powell, R., 1998. An internally consistent thermodynamic data set for phases of petrological interest. Journal of Metamorphic Geology 16, 309–343.
663
Huang, X.L., Niu, Y.L., Xu, Y.G., Yang, Q.J., Zhong, J.W., 2010. Geochemistry of
664
TTG and TTG-like gneisses from Lushan–Taihua complex in the southern North
665
China Craton: Implications for late Archean crustal accretion. Precambrian
666
Research 182, 43–56.
667
Huang, X.L., Wilde, S.A, Yang, Q.J., Zhong, J.W., 2012. Geochronology and
668
petrogenesis of gray gneisses from the Taihua Complex at Xiong'er in the
669
southern segment of the Trans-North China Orogen: Implications for tectonic
670
transformation in the Early Paleoproterozoic. Lithos 134–135, 236–252.
671
Huang, X.L., Wilde, S.A, Zhong, J.W., 2013. Episodic crustal growth in the southern
672
segment of the Trans-North China Orogen across the Archean–Proterozoic
673
boundary. Precambrian Research 233, 337–357.
674
Jiang, Z.S., Wang, G.D., Xiao, L.L., Diwu, C.R., Lu, J.S., Wu, C.M., 2011.
675
Paleoproterozoic metamorphic P–T–t path and tectonic significance of the
676
Luoning metamorphic complex at the southern terminal of the Trans-North
677
China Orogen,Henan Province. Acta Petrologica Sinica 27, 3701–3717 (in
678
Chinese with English abstract).
31
679
Kang, C.H., Li, M.X., 1988. Rehabilitation of the characteristics of the metamorphic
680
original rocks under the Taihua Group in Tongguan region, Shanxi province,
681
Journal of Xi’an College of Geology 10, 1–13 (in Chinese with English
682
abstract).
683 684
Kohn, M.J., Spear, F., 2000. Retrograde net transfer reaction insurance for pressure–temperature estimates. Geology 28, 1127–1130.
685
Kröner, A., Wilde, S.A., Li, J.H., Wang, K.Y., 2005. Age and evolution of a late
686
Archean to early Palaeoproterozoic upper to lower crustal section in the
687
Wutaishan/Hengshan/Fuping terrain of northern China. Journal of Asian Earth
688
Science 24, 577–595.
689
Kröner, A., Wilde, S.A., Zhao, G.C., O’Brien, P.J., Sun, M., Liu, D.Y., Wan, Y.S.,
690
Liu, S.W., Guo, J.H., 2006. Zircon geochronology of mafic dykes in the
691
Hengshan Complex of northern China: evidence for late Palaeoproterozoic
692
rifting and subsequent high pressure event in the North China Craton.
693
Precambrian Research 146, 45–67.
694 695 696 697 698
Kusky, T.M., 2011. Geophysical and geological tests of tectonic models of the North China Craton. Gondwana Research 20, 26–35. Kusky, T.M., Li, J.H., 2003. Paleoproterozoic tectonic evolution of the North China craton. Journal of Asian Earth Sciences 22, 23–40. Lal, R.K., 1993. Internally consistent recalibrations of mineral equilibria for
699
geothermobarometry
involving
garnet–orthopyroxene–plagioclase–quartz
700
assemblages and their application to the South Indian granulites. Journal of
32
701
Metamorphic Geology 11, 855–866.
702
Li, X.H., Liu, Y., Li, Q.L., Guo, C.H., Chamberlain, K.R., 2009. Precise
703
determination of Phanerozoic zircon Pb/Pb age by multicollector SIMS without
704
external standardization. Geochemistry Geophysics Geosystem 10, Q04010.
705
doi:10.1029/cGC002400.
706
Liu, D.Y., Nutman, A.P., Compston, W., Wu, J.S., Shen, Q.H., 1992. Remnants of
707
≥3800 Ma crust in the Chinese part of the Sino-Korean Craton. Geology 20,
708
339–342.
709
Liu, D.Y., Wilde, S.A., Wan, Y.S., Wang, S.Y., Valley, J.W., Kita, N., Dong, C.Y.,
710
Xie, H.Q., Yang, C.X., Zhang, Y.X., Gao, L.Z., 2009. Combined U–Pb, hafnium
711
and oxygen isotope analysis of zircons from meta-igneous rocks in the southern
712
North China Craton reveal multiple events in the Late Mesoarchean–Early
713
Neoarchean. Chemical Geology 261, 140–154.
714
Liu, F.L., 1997. The Metamorphic Reaction and Water Activity of Basic Granulite in
715
the Datong–Huaian Region. Acta Petrologica Sinica 13, 27–43 (in Chinese with
716
English abstract).
717 718
Liu, S.W., 1996. Study on the P–T path of granulites in Fuping area, Hebei Province. Geological Journal of Universities 2, 75–84 (in Chinese with English abstract).
719
Liu, S.W., Shu, G.M., Pan, Y.M., Dang, Q.N., 2004. Electron-microprobe dating of
720
monazite and metamorphic age of Wutai Group, Wutai Mountains. Geological
721
Journal of China Universities 10, 356–363 (in Chinese with English abstract).
722
Liu, S.W., Zhang, C., Liu, C.H., L, Q.G., Lü, Y.J., Yu, S.Q., Tian, W., Feng, Y.G.,
33
723
2007. EPMA Th–U–Pb dating of monazite for Zhongtiao and Lüliang
724
Precambrian metamorphic complexes. Earth Science Frontiers 14, 64–74 (in
725
Chinese with English abstract).
726
Liu, S.W., Zhao, G.C., Wilde, S.A., Shu, G.M., Sun, M., Li, Q.G., Tian, W. Zhang, J.,
727
2006. Th–U–Pb monazite geochronology of the Lüliang and Wutai Complexes:
728
Constraints on the tectonothermal evolution of the Trans-North China Orogen.
729
Precambrian Research 148, 205–224.
730
Lu, J.S., Wang, G.D., Wang, H., Chen, H.X., Peng, T., Wu, C.M., 2015. Zircon SIMS
731
U–Pb geochronology of the Lushan terrane: dating metamorphism of the
732
southwestern terminal of the Palaeoproterozoic Trans-North China Orogen.
733
Geological Magazine152, 367–377.
734
Lu, J.S., Wang, G.D., Wang, H., Chen, H.X., Wu, C.M., 2013. Metamorphic P–T–t
735
paths retrieved from the amphibolites, Lushan terrane, Henan Province and
736
reappraisal of the Paleoproterozoic tectonic evolution of the Trans-North China
737
Orogen. Precambrian Research 238, 61−67.
738
Lu, J.S., Wang, G.D., Wang, H., Chen, H.X., Wu, C.M., 2014. Palaeoproterozoic
739
metamorphic evolution and geochronology of the Wugang block, southeastern
740
terminal of the Trans-North China Orogen. Precambrian Research 251,
741
197−211.
742 743 744
Lu, L.Z., 1991. Metamorphic P–T–t paths and their geodynamic implications. Overseas Precambrian Geology 3, 4–20 (in Chinese). Ludwig, K.R., 2003. Isoplot 3.0-A geochronological toolkit for Micro-soft Excel.
34
745
Berkeley Geochronology Center, Special Publication 4, 1–70.
746
Ma, J., Wang, R.M., 1994. Reviews in garnet–clinopyroxene geothermometers and
747
geobarometers with their application to granulite: the comparison of Miyun
748
(Zunhua) and Xuanhua granulite forming conditions. In: Qian, X.L., Wang, R.M.
749
(eds.) Geological evolution of the granulite Terrane in North Part of the North
750
China Craton. Seismological Press, Beijing, pp. 71–88 (in Chinese with English
751
abstract).
752
Mao, D.B., Zhong, C.T., Chen, Z.H., Lin, Y.X., Li, H.M., Hu, X.D., 1999. Isotopic
753
ages and geological implications of high-pressure mafic granulites in the
754
northern Chengde area, Hebei Province, China. Acta Petrologica Sinica 15,
755
524–534.
756
Mei, H.L., 1994. Metamorphic P–T–t paths and tectonic evolution of early
757
Proterozoic rocks from the Zhongtiao Mountains, southern Shanxi. Geological
758
Review 40, 36–45 (in Chinese with English abstract).
759 760
Miyashiro, A., 1961. Evolution of metamorphic belts. Journal of Petrology 2, 277–311.
761
Newton, R.C., Charlum, T.V., Kleppa, O.J., 1980. Thermochemistry of the high
762
structural state plagioclases. Geochemica Cosmochimica Acta 44, 933–941.
763
Nicollet, C., Goncalves, P., 2005. Two contrasted P–T–time paths of coronitic
764
metanorites of the French Massif Central: are reaction textures reliable guides to
765
metamorphic histories? Journal of Metamorphic Geology 23, 97–105.
766
O’Brien, P.J., Walte, N., Li, J.H., 2005. The petrology of two distinct granulite types
35
767
in the Hengshan Mts, China, and tectonic implications. Journal of Asian Earth
768
Sciences 24, 615–627.
769
Pattison, D.R.M., 1992. Stability of andalusite and sillimanite and the Al2SiO5 triple
770
point: constraints from the Ballachulish aureole, Scotland. Journal of Geology
771
100, 423–446.
772
Peng, P., Wang, X.P., Windley, B.F., Guo, J.H., Zhai, M.G., Li, Y., 2014. Spatial
773
distribution of ~1950–1800 Ma metamorphic events in the North China Craton:
774
Implications for tectonic subdivision of the craton. Lithos 202–203, 250–266.
775
Peterson, J.W., Chacko, T., Kuehner, S.M., 1991. The effects of fluorine on the
776
vapor-absent melting of phlogopite + quartz: implications for deep crustal
777
processes. American Mineralogist 76, 470–476.
778 779
Powell, P., Holland, T.J.B., 2008. On thermobarometry. Journal of Metamorphic Geology 26, 155–179.
780
Qi, J.Y., 1991. Amphiboles from basic metamorphic rocks in the Archeozoic Taihua
781
Group and its genetic significance. Journal of Hebei College of Geology 14,
782
144–157 (in Chinese with English abstract).
783
Qi, J.Y., 1992. Metamorphic rock series of Taihua Group and conditions for its
784
formation in eastern Qinling. Scientia Geologica Sinica 8(Supplementary),
785
95–107 (in Chinese with English abstract).
786
Qian, J.H., Wei, C.J., 2016. P–T–t evolution of garnet amphibolites in the
787
Wutai-Hengshan area, North China Craton: insights from phase equilibria and
788
geochronology. Journal of Metamorphic Geology 34, 423–446.
36
789
Qian, J.H., Wei, C.J., Clarke, G.L., Zhou, X.W., 2015. Metamorphic evolution and
790
zircon ages of garnet–orthoamphibole rocks in southern Hengshan, North China
791
Craton: insight into the regional Paleoproterozoic P–T–t history. Precambrian
792
Research 256, 223–240.
793
Qian, J.H., Wei, C.J., Zhou, X.W., Zhang, Y.H., 2013. Metamorphic P–T paths and
794
new zircon U–Pb age data for garnet–mica schist from the Wutai Group, North
795
China Craton. Precambrian Research 233, 282–296.
796
Qu, J.F., Li, J.Y., Liu, J.F., 2012. Geochronological study on the Fenghuangzui
797
complex of Dantazi Group at northern Hebei Province. Acta Petrologica Sinica
798
28, 2879–2889 (in Chinese with English abstract).
799
Richardson, S.W., England, P.C., 1979. Metamorphic consequences of crustal eclogite
800
production in over thrust orogenic zone. Earth and Planetary Science Letters 42,
801
183–190.
802
Sandiford, M., Powell, R., 1986. Deep crustal metamorphism during continental
803
extension: modern and ancient examples. Earth and Planetary Science Letters 79
804
(1–2), 151–158.
805
Santosh, M., 2010. Assembling North China Craton within the Columbia
806
supercontinent: the role of double-sided subduction. Precambrian Research 178,
807
149–167.
808
Santosh, M., Sajeev, K., Li, J.H., 2006. Extreme crustal metamorphism during
809
Columbia supercontinent assembly: evidence from North China Craton.
810
Gondwana Research 10, 256–266.
37
811
Sláma, J., Košler, J., Condon, D.J., Crowley, J.L., Gerdes, A., Hanchar, J.M.,
812
Horstwood, M.S.A., Morris, G.A., Nasdala, L., Norberg, N., Schaltegger, U.,
813
Schoene, B., Tubrett, M.N., Whitehouse, M.J., 2008. Plešovice zircon—A new
814
natural reference material for U–Pb and Hf isotopic microanalysis. Chemical
815
Geology 249, 1–35.
816 817 818 819
Spear, F.S., 1992. Thermobarometry and P–T paths from granulite facies rocks: an introduction. Precambrian Research 55, 201–207. Spear, F.S., 1993. Metamorphic phase equilibria and pressure–temperature–time paths. Mineralogical Society of America, Washington, D. C., pp. 15–22.
820
Spear, F.S., Hickmott, D.D., Selverstone, J., 1990. Metamorphic consequences of
821
thrust emplacement, Fall Mountain, New Hampshire. Geological Society of
822
America Bulletin 102, 1344–1360.
823 824 825 826
Spear, F.S., Florence, F., 1992. Thermobarometry in granulites: pitfalls and new approaches. Precambrian Research 55, 209–241. Stacey, J.S., Kramers, J.D., 1975. Approximation of terrestrial lead isotope evolution by a two-stage model. Earth and Planetary Science Letters 26, 207–221.
827
Tajcmanová, L., Connolly, J.A.D., Cesare, B., 2009. A thermodynamic model for
828
titanium and ferric iron solution in biotite. Journal of Metamorphic Geology 27,
829
153–64.
830
Trap, P., Faure, M., Lin, W., Breton, N.L., Monié, P., 2012. The Paleoproterozoic
831
evolution of the Trans-North China Orogen: Toward a comprehensive model.
832
Precambrian Research 222–223, 191–211.
38
833
Trap, P., Faure, M., Lin, W., Meffre, S., 2009b. The Lüliang Massif: a key area for the
834
understanding of the Palaeoproterozoic Trans-North China Belt, North China
835
Craton. Journal of the Geological Society, London, Special Publication 33,
836
99–125.
837
Trap, P., Faure, M., Lin, W., Monié, P., 2007. Late Palaeoproterozoic (1900–1800 Ma)
838
nappe stacking and polyphase deformation in the Hengshan–Wutaishan area:
839
Implications for the understanding of the Trans-North China Belt, North China
840
Craton. Precambrian Research 156, 85–106.
841
Trap, P., Faure, M., Lin, W., Monié, P., Bruguier, O., 2008. Contrasted tectonic styles
842
for the Paleoproterozoic evolution of the North China Craton: evidence for a 2.1
843
Ga thermal and tectonic event in the Fuping Massif. Journal of Structure
844
Geology 30, 1109–1125.
845
Trap, P., Faure, M., Lin, W., Monié, P., Meffre, S., Melletton, J., 2009a. The
846
Zanhuang Massif, the second and eastern suture zone of the Paleoproterozoic
847
Trans-North China Orogen. Precambrian Research 172, 80–98.
848
Vernon, R.H., White, R.W., Clarke, G.L., 2008. False metamorphic events inferred
849
from misinterpretation of microstructural evidence and P–T data. Journal of
850
Metamorphic Geology 26, 437–449.
851
Waldbaum, D.R., Thompson, J.B., 1968. Mixing Properties of Sanidine Crystalline
852
Solutions. 2. Calculations Based On Volume Data. American Mineralogist 53,
853
2000.
854
Wan, Y.S., Wilde, S.A., Liu, D.Y., Yang, C.X., Song, B., Yin, X.Y., 2006. Further
39
855
evidence for ~1.85 Ga metamorphism in the Central Zone of the North China
856
Craton: SHRIMP U–Pb dating of zircon from metamorphic rocks in the Lushan
857
area, He’nan Province. Gondwana Research 9, 189–197.
858
Wang, G.D., Lu, J.S., Wang, H., Chen, H.X., Xiao, L.L., Diwu, C.R., Ji, J.Q., Wu, 40
Ar/39Ar dating of
859
C.M., 2013. LA–ICP–MS U–Pb dating of zircons and
860
amphiboles of the Taihua Metamorphic Complex, Huashan, southern terminal of
861
the Paleoprotorozoic Trans-North China Orogen. Acta Petrologica Sinica 29,
862
3099–3114 (in Chinese with English abstract).
863
Wang, G.D., Wang, H., Chen, H.X., Lu, J.S., Xiao, L.L., Wu, C.M., 2012. U–Pb
864
dating of zircons from metamorphic rocks of the Taihua Metamorphic Complex,
865
Huashan, Southern Margin of the Trans-North China Orogen. Acta Geologica
866
Sinica 86, 1541–1551 (in Chinese with English abstract).
867
Wang, G.D., Wang, H., Chen, H.X., Lu, J.S., Wu, C.M., 2014. Metamorphic
868
evolution and zircon U–Pb geochronology of the Mts. Huashan amphibolites:
869
Insights into the Palaeoproterozoic amalgamation of the North China Craton.
870
Precambrian Research 245, 100−114.
871
Wang, G.D., Wang, H., Chen, H.X., Zhang, Bo., Zhang, Q., Wu, C.M., 2016.
872
Geochronology and geochemistry of the TTG and potassic granite of the Taihua
873
complex, Mts. Huashan: implications for crustal evolution of the southern North
874
China
875
http://dx.doi.org/10.1016/j.precamres.2016.11.006.
876
Craton.
Precambrian
Research,
Wang, K.Y., Zhou, S.P., Hao, J., 1996. The metamorphism and significance of
40
877
kyanitebearing assemblages from the original jingangku formation of Wutaishan
878
area. Acta Petrologica Sinica 12, 88–98 (in Chinese with English abstract).
879
Wang, R.M., Chen, Z.Z., Chen, F., 1991. Grey tonalitic gneiss and high-pressure
880
granulite inclusions in Hengshan, Shanxi Province, and their geological
881
significance. Acta Petrologica Sinica 7, 36–46 (in Chinese with English
882
abstract).
883
Wang, Z.H., Wilde, S.A., Wan, J.L., 2010. Tectonic setting and significance of
884
2.3–2.1 Ga magmatic events in the Trans-North China Orogen: new constraints
885
from
886
Hengshan–Wutai–Fuping area. Precambrian Research 178, 27–42.
the
Yanmenguan
mafic–ultramafic
intrusion
in
the
887
White, R.W., Powell, R., Holland, T.J.B., 2007. Progress relating to calculation of
888
partial melting equilibria for metapelites. Journal of Metamorphic Geology 25,
889
511–527.
890
White, R.W., Powell, R., Holland, T.J.B., Worley, B.A., 2000. The effect of TiO2 and
891
Fe2O3 on metapelitic assemblages at greenschist and amphibolite facies
892
conditions:
893
K2O–FeO–MgO–Al2O3–SiO2–H2O–TiO2–Fe2O3.
894
Geology 18, 497–511.
895 896 897 898
mineral
equilibria
calculations
in
Journal
the of
system
Metamorphic
Whitney, D.L., Evans, B.W., 2010. Abbreviations for names of rock-forming minerals. American Mineralogist 95, 185–187. Wu, C.M., Chen, H.X., 2015. Revised Ti-in-biotite geothermometer for ilmenite-or rutile-bearing crustal metapelites. Science Bulletin 60 (1), 116–121.
41
899
Wu, C.M., Cheng B.H., 2006. Valid garnet-biotite (GB) geothermometry and
900
garnet–aluminum
silicate–plagioclase–quartz
901
metapelitic rocks. Lithos 89, 1–23.
(GASP)
geobarometry
in
902
Wu, C.M., Lu, J.S., Wang, G.D., 2014. Determination of Pressure–Temperature
903
Conditions of Retrograde Symplectitic Assemblages in Granulites and
904
Amphibolites. Global Journal Earth Science and Engineering 1, 71–83.
905
Wu, C.M., Zhang J., Ren L.D., 2004. Empirical garnet–biotite–plagioclase–quartz
906
(GBPQ) geobarometry in medium to high-grade metapelitic gneisses. Journal of
907
Petrology 45, 1907–1921.
908
Wu, J.S., Geng, Y.S., Shen, Q.H., Wan, Y.S., Liu, D.Y., Song, B., 1998. Archean
909
Geological
Characteristics
and
Tectonic
Evolution
of
China-Korea
910
Paleo-Continent. Geological Publishing House, Beijing, pp. 192–211 (in
911
Chinese with English abstract).
912
Xiao, L.L., Liu, F.L., Chen, Y., 2014. Metamorphic P–T–t paths of the Zanhuang
913
metamorphic complex: implications for the Paleoproterozoic evolution of the
914
Trans-North China Orogen. Precambrian Research 255, 216–235.
915
Xiao, L.L., Wang, G.D., Wang, H., Jiang, Z.S., Diwu, C.R., Wu, C.M., 2013. Zircon
916
U–Pb geochronology of the Zanhuang metamorphic complex: reappraisal of the
917
Paleoproterozoic amalgamation of the Trans-North China Orogen. Geological
918
Magazine 150, 756–764.
919
Xiao, L.L., Wu, C.M., Zhao, G.C., Guo, J.H., Ren, L.D., 2011. Metamorphic P–T
920
paths of the Zanhuang amphibolitic gneisses and metapelitic gneisses:
42
921
Constraints on the tectonic evolution of the Paleoproterozoic Trans-North China
922
Orogen. International Journal of Earth Sciences 100, 717–739.
923
Yang, C.X., 2008. Zircon SHRIMP U–Pb ages, geochemical characteristics and
924
environmental evolution of the Early Precambrian metamorphic series in the
925
Lushan area, Henan, China. Geological Bulletin of China 27, 517–533 (in
926
Chinese with English abstract).
927
Yu, L.J., Wang, K.Y., Wang, Z.H., Li, J.L., Fang, A.M., 2001. Early Proterozoic
928
high-pressure metamorphism in the Wutaishan. Acta Petrologica Sinica 17,
929
301–313 (in Chinese with English abstract).
930
Yu, X.Q., Liu, J.L., Li, C.L., Chen, S.Q., Dai, Y.P., 2013. Zircon U–Pb dating and Hf
931
isotope analysis on the Taihua Complex: Constraints on the formation and
932
evolution of the Trans-North China Orogen. Precambrian Research 230, 31–34.
933
Zhai, M.G., Bian, A.G., Zhao, T.P., 2000. The amalgamation of the supercontinent of
934
North China craton at the end of the Neoarchaean and its breakup during late
935
Palaeoproterozoic and Mesoproterozoic. Science in China Series D: Earth
936
Sciences 43, 219–232.
937
Zhai, M.G., Guo, J.H., Liu, W.J., 2005. Neoarchean to Paleoproterozoic continental
938
evolution and tectonic history of the North China Craton: A review. Journal of
939
Asian Earth Sciences 24, 547–561.
940
Zhai, M.G., Guo, J.H., Yan, Y.H., Li, Y.G., Han, X.L., 1993. Discovery of
941
high-pressure basic granulite terrain in north China Archaean Craton and
942
preliminary study. Science in China Series B 36, 1402–1408.
43
943
Zhai, M.G., Li, T.S., Peng, P., Hu, B., Liu, F., Zhang, Y.B., Guo, J.H., 2010.
944
Precambrian key tectonic events and evolution of the North China Craton. In:
945
Kusky, T.M., Zhai, M.G., Xiao, W.J. (Eds.), The Evolving Continents. Journal
946
of the Geological Society, London, Special Publications 338, 235–262.
947 948 949 950
Zhai, M.G., Peng, P., 2007. Paleoproterozoic events in North China Craton. Acta Petrologica Sinica 23, 2665–2682 (in Chinese with English abstract). Zhai, M.G., Santosh, M., 2011. The early Precambrian odyssey of North China Craton. A synoptic overview. Gondwana Research 20, 6–25.
951
Zhang, J., Zhao, G.C., Li, S.Z., Sun, M., Chan, L.S., Shen, W.L., Liu, S.W., 2012.
952
Structural and aeromagnetic studies of the Wutai Complex: implications for the
953
tectonic evolution of the Trans-North China Orogen. Precambrian Research
954
222–223, 212–229.
955
Zhang, J., Zhao, G.C., Li, S.Z., Sun, M., Liu, S.W., Wilde, S.A., Kröner, A., Yin,
956
C.Q., 2007. Deformation history of the Hengshan Complex: implications for the
957
tectonic evolution of the Trans-North China Orogen. Journal of Structural
958
Geology 29, 933–949.
959
Zhang, J., Zhao, G.C., Li, S.Z., Sun, M., Wilde, S.A., Liu, S.W., Yin, C.Q., 2009.
960
Polyphase deformation of the Fuping Complex, Trans-North China Orogen:
961
structures, SHRIMP U–Pb zircon ages and tectonic implications. Journal of
962
Structural Geology 31, 177–193.
963
Zhao, G.C., Cawood, P.A., Li, S.Z., Wilde, S.A., Sun, M., Zhang, J., He, Y.H., Yin,
964
C.Q., 2012. Amalgamation of the North China Craton: Key issues and
44
965
discussion. Precambrian Research 222–223, 55–76.
966
Zhao, G.C., Cawood, P.A., Lu, L.Z., 1999. Petrology and P–T history of the Wutai
967
amphibolites: implications for tectonic evolution of the Wutai Complex, China.
968
Precambrian Research 93, 181–199.
969
Zhao, G.C., Cawood, P.A., Wilde, S.A., Lu, L.Z., 2001b. High-pressure granulites
970
(retrograded eclogites) from the Hengshan Complex, North China Craton:
971
petrology and tectonic implications. Journal of Petrology 42, 1141–1170.
972
Zhao, G.C., Cawood, P.A., Wilde, S.A., Sun, M., Lu, L.Z., 2000a. Metamorphism of
973
basement rocks in the Central Zone of the North China Craton: implications for
974
Paleoproterozoic tectonic evolution. Precambrian Research 103, 55–88.
975
Zhao, G.C., Kröner, A., Wilde, S.A., Sun, M., Li, S.Z., Li, X.P., Zhang, J., Xia, X.P.,
976
He, Y.H., 2007. Lithotectonic elements and geological events in the
977
Hengshan–Wutai–Fuping belt: a synthesis and implications for the evolution of
978
the Trans-North China Orogen. Geological Magazine 144, 753–775.
979
Zhao, G.C., Sun, M., Wilde, S.A., Li, S.Z., 2005. Neoarchaean to Palaeoproterozoic
980
evolution of the North China Craton: Key issues revisited. Precambrian
981
Research 136, 177–202.
982
Zhao, G.C., Wilde, S.A., Cawood, P.A., Lu, L.Z., 1998. Thermal evolution of the
983
Archaean basement rocks from the eastern part of the North China Craton and
984
its bearing on tectonic setting. International Geology Review 40, 706–721.
985
Zhao, G.C., Wilde, S.A., Cawood, P.A., Lu, L.Z., 2000b. Petrology and P–T path of
986
the Fuping mafic granulites: implications for tectonic evolution of the central
45
987
zone of the North China Craton. Journal of Metamorphic Geology 18, 375–391.
988
Zhao, G.C., Wilde, S.A., Cawood, P.A., Sun, M., 2001a. Archean blocks and their
989
boundaries in the North China Craton: lithological, geochemical, structural and
990
P–T path constraints and tectonic evolution. Precambrian Research 107, 45–3.
991
Zhao, G.C., Wilde, S.A., Cawood, P.A., Sun, M., 2002. SHRIMP U–Pb zircon ages of
992
the Fuping Complex: Implications for Late Archean to Paleoproterozoic
993
accretion and assembly of the North China Craton. American Journal of Science
994
302, 191–226.
995
Zhao, G.C., Wilde, S.A., Sun, M., Guo, J.H., Kröner, A., Li, S.Z., Li, X.P., Wu, C.M.,
996
2008a. SHRIMP U–Pb zircon geochronology of the Huaian Complex:
997
constraints on Late Archean to Paleoproterozoic crustal accretion and collision
998
of the Trans-North China Orogen. American Journal of Science 308, 270–303.
999
Zhao, G.C., Wilde, S.A., Sun, M., Li, S.Z., Li, X.P., Zhang, J., 2008b. SHRIMP U–Pb
1000
zircon ages of granitoid rocks in the Lüliang Complex: Implications for the
1001
accretion and evolution of the Trans-North China Orogen. Precambrian
1002
Research 160, 213–226.
1003
Zhao, G.C., Li, S.Z., Zhang, J., Xia, X.P., 2010a. A comment on tectonic evolution of
1004
the Hengshan–Wutai–Fuping complexes and its implication for the Trans-North
1005
China Orogen. Precambrian Research 176, 94–98.
1006
Zhao, G.C., Yin, C.Q., Guo, J.H., Sun, M., Li, S.Z., Li, X.P., Wu, C.M., Liu, C.H.,
1007
2010b. Metamorphism of the Lüliang amphibolite: implications for the tectonic
1008
evolution of the North China Craton. American Journal of Science 310,
46
1009
1480–1502.
1010
Zhao, G.C., Zhai, M.G., 2013. Lithotectonic elements of Precambrian basement in the
1011
North China Craton: Review and tectonic implications. Gondwana Research 23,
1012
1207–1240.
1013
Zhou, H.W., Li, X.H., Zhong, Z.Q., Liu, Y., Xu, Q.D., 1997. Geochemistry of
1014
amphibolites within the Taihua complex from the Xiao Qinling area, western
1015
Henan and its tectonic implication. Geochimica 26, 87–100 (in Chinese with
1016
English abstract).
1017
Zhou, H.W., Zhong, Z.Q., Ling, W.L., Zhong, G.L., Xu, Q.D., 1998. Sm–Nd isochron
1018
for the amphibolites within Taihua complex from the Xiao Qinling area, western
1019
Henan and its geological implications. Geochimica 27, 367–372 (in Chinese
1020
with English abstract).
1021
Zhu, R.X., Zheng, T.Y., 2009. Destruction geodynamics of the North China craton
1022
and its Paleoproterozoic plate tectonics. Chinese Science Bulletin 19,
1023
3354–3366.
1024
Figure captions
1025 1026
Fig. 1. (a) Geological sketch map of the North China Craton showing the Mts.
1027
Huashan metamorphic terrane in the Trans-North China Orogen (from Zhao et al.
1028
1998, 2005) and (b) Geological sketch map of the Mts. Huashan metamorphic terrane,
1029
modified after the 1:200000 Weinan and Luonan Geological Maps. Sample locations
1030
are depicted.
47
1031
Fig. 2. Photomicropetrographs of the Mts. Huashan pelitic granulite samples (a)
1032
S18, (b–c) S25 and (d) S37, respectively. Dotted lines with arrowheads represent the
1033
EMP analytical profiles of the garnets. Mineral inclusions of Bt1 + Pl1 + Qz1 ± Ilm1
1034
within the garnet porphyroblasts comprise the prograde (M1) mineral assemblages.
1035
The metamorphic peak mineral assemblages (M2) are consisted of garnet
1036
porphyroblasts (Grt2) and matrix minerals Opx2 + Bt2+ Pl2 + Qz2 ± Ilm2 ± Mag2 ±
1037
zircon. The retrograde symplectic assemblages (M3) are consisted of Bt3 + Pl3 + Qz3 ±
1038
Opx3.
1039 1040 1041 1042
Fig. 3. X-ray compositional mapping of Fe, Mg, Ca and Mn of garnet porphyroblasts of the pelitic granulite samples (a) S18, (b) S25 and (c) S37. Fig. 4. Analytical chemical profiles of garnet porphyroblasts in the Mts. Huashan pelitic granulite samples (a) S18, (b) S25 and (c) S37.
1043
Fig. 5. Metamorphic P–T paths retrieved from the Mts. Huashan pelitic granulite
1044
samples (a) S18, (b) S25 and (c) S37. The Al2SiO5 phase transition lines are after
1045
Holdaway and Mukhopadhyay (1993), and the dashed lines are after Pattison (1992).
1046
The metamorphic facies and metamorphic facies series are from Spear (1993, p.
1047
15–22).
1048
Fig. 6. The P–T pseudosection calculated for the Huashan pelitic granulite
1049
(sample S18) in the NCKFMASHT system. The isopleths of Xgrs, XAlm and XPyr of
1050
garnet are also shown.
1051 1052
Fig. 7. The representative cathodoluminescence (CL) images of zircons separated from (a) pelitic granulite sample S7 and (b) pelitic granulite sample S18.
48
1053 1054
Fig. 8. The U–Pb concordia diagrams of analytical zircons of (a) pelitic granulite sample S7 and (b) pelitic granulite sample S18.
Table caption
1055 1056 1057
1058 1059
1060 1061
1062 1063
1064 1065
1066 1067
1068
Table 1. Representative compositions of garnet (cations are calculated based on 12 oxygens). Table 2. Representative compositions of orthopyroxene (cations are calculated based on 6 oxygens). Table 3. Representative compositions of biotite (cations are calculated based on 11 oxygens). Table 4. Representative compositions of plagioclase (cations are calculated based on 8 oxygens). Table 5. The P–T conditions of different metamorphic stages of the representative pelitic granulites of the Huashan Metamorphic Complex. Table 6. SIMS U–Pb geochronological data of zircons separated from the representative pelitic granulites of the Huashan Metamorphic Complex. Table 7. Summary of metamorphic ages for the Taihua Metamorphic Complex.
1069
49
100°
105°
110°
115°
125°
120°
130°
Abbreviations for metamorphic complexes in Fig.1(a):
Changchun
(a)
SJ
0
200 400 km
Duolun
Bayan Obo WC
GY
40° AL
Yinshan Block HL
WL JP
NH
40°
WD JN XH MY HA Khondalite Belt EH Beijing QL HS WT FP
Xi ' An
LG Pyeonrang
SL
EASTERN BLOCK
WESTERN BLOCK LL Taiyuan ZH Ordos Block 35°
NL
Gyeonggi
ES 35°
TRANS - NORTH WS CHINA OROGEN ZT DF
TH Hidden basement in the Eastern and Western Block
Xinyang Shanghai
Exposed basement in the Eastern and Western Block Hidden basement in the Paleoproterozoic orogens
30°
Exposed basement in the Khondalite Belt in the Western Block
Wuhan
Exposed basement in the Trans-North China orogen Exposed basement in the Jiao-Liao-Ji Belt in the Eastern Block Major fault
115°
110° 10´
109° 45´
125°
120°
110° 15´
110° 30´
Huayin
(b)
Huaxian
AL – Alashan; CD – Chengde; DF – Dengfeng; EH – Eastern Hebei; ES – Eastern Shandong; FP – Fuping; GY – Guyang; HA – Huai'an; HL – Helanshan; HS – Hengshan; JN – Jining; LG – Langrim; LL – Lüliang; MY– Miyun; NH – Northern Hebei; NL – Northern Liaoning; QL – Qianlishan; SJ – Southern Jilin; SL – Southern Liaoning; TH – Taihua; WD– Wulashan-Daqingshan; WL– Western Liaoning; WS – Western Shandong; WT – Wutai; XH – Xuanhua; ZH – Zanhuang; ZT – Zhongtiao.
Tongguan
N
110° 45´ 0 10000m
34° 30´
34° 30´ S37
Arth 1
S7
Arth 2
Arth 1
S18
S25
Pt 1 xl 3
34° 00´
110°30´
110°15´ Lower Taihua Group (Arth 1 )
Upper Taihua Group (Arth 2 )
Upper Xiong'er Group
Proterozoic granite
Μesozoic granite
Sample location
110°45´
34° 00´
Fig. 1
( a)
(b)
Bt 2
Opx 2
Opx 2 Opx 3 Bt 2
Bt 1 Ilm 1
Bt 2 Pl 3 +Bt 3
Grt 2
Grt 2
Qz 1
Bt 1
Bt 3 +Pl 3
Pl 1
Opx 2 Bt 2
1000µm
Opx 2
(c)
(d)
Bt 2
Opx 2
Bt 2
Opx 2
Pl 2 Pl 3 +Bt 3
Bt 2 +Opx 2 +Pl 2
Grt 2
1000µm
St 1
Qz 1 +Pl 1 +Bt 1 Opx 3 +Bt 3 +Pl 3
Grt 2 Bt 1 Pl 1 +Bt 1 +Qz 1
Ap 1
Pl 3 +Bt 3
Opx 2
2000µm
Pl 2 +Bt 2
2000µm
Fig. 2
(a) S18
Fe 500µm
Mg 500µm
Ca 500µm
Mn 500µm
Mg 500µm
Ca 500µm
Mn 500µm
Mg 1 mm
Ca 1 mm
Mn 1 mm
(b) S25
Fe 500µm
(c) S37
Fe
1 mm
Fig. 3
(a) 0.8
S18
0.6
0.4
Xalm
Xpyr
Xgros
Xsps
Fe/(Fe+Mg)
0.2
0.0 -2 0rim 246
12
222426 core2830 34 384042 46485052 rim
(b) 0.8
S25
0.6
0.4
0.2 Xalm
Xpyr
Xgros
Xsps
Fe/(Fe+Mg)
0.0 -2 0rim 2 4 6 8 101214161820222426 485052 core28303234363840424446rim
(c) S37 0.8
0.6
0.4
Xalm
Xpyr
Xgros
Xsps
Fe/(Fe+Mg)
0.2
0.0 -20 rim 2 4 6 810121416182022242628core 3032343638404244464850525456 586062 rim
Fig. 4
(a)
(b) 10
10 M2:730°C 7.2kbar (GBPQ) M2:760°C 6.8kbar (GOPQ) M3:670°C 5.0kbar (GBPQ) 8
S18 8
EA
M2:730°C 7.0kbar (GBPQ) M2:760°C 6.8kbar (GOPQ) M3:680°C 4.2kbar (GBPQ) M3:570°C 4.1kbar (GOPQ) EA M2
M2
Ky
Am
6
6
Ky
Gr
Sil
Am
M3
Gr
Sil
4
M3
4 And
And
2
2 500
600
700
800
900
500
600
700 T (°C)
T (°C) (c)
S25
800
900
(d) 10
10
S18 S25 S37
S37 M2 8
8
EA
Gr EA
6
Am
Ky
Ky
M3
M1
6 Gr
4 And
Sil
Sil
Am
M1:520~530°C (Ti in Bt) M2:740°C 8.6kbar (GBPQ) M2:810°C 7.3kbar (GOPQ) M3:740°C 6.4kbar (GBPQ)
4 And 2
2 500
600
700 T (°C)
800
900
500
600
700
800
900
T (°C)
Fig. 5
NCKFMASHT 10000
Na 2 O CaO K 2 O FeO MgO Al 2 O 3
SiO 2 H 2 O TiO 2
3.94 3.15 2.38 9.93 5.87 17.69 52.64 0.56 0.85
(wt % ) Opx Bt Pl Grt Kfs Ilm Qz Liq Opx Bt Pl Grt Kfs Ilm Liq
Opx Bt Pl Grt Kfs Qz Ru
8400
0 . 27
0 . 25 Opx Bt Pl Grt Kfs Qz
0 . 29
M2
Opx Bt Pl Grt Kfs Liq
0 . 06
0 . 05
0 . 65 Opx Bt Pl Grt Kfs Ilm Qz Ru
6800
0 . 67
Opx Bt Pl Grt Kfs Ilm Qz
0 . 69 0.70
5200
M3
Opx Bt Pl Kfs Qz Opx Bt Pl Crd Kfs Liq
3600
Opx Bt Crd Pl Grt Kfs Ilm Qz
Opx Bt Pl Crd Kfs Qz Liq Opx Bt Pl Crd Grt Kfs Qz Opx Bt Pl Crd Ilm
Opx Bt Pl Crd Kfs Qz
Opx Bt Pl Crd Kfs Qz Ilm
Opx Bt Pl Crd Kfs Ilm Qz
Opx Bt Pl Crd Kfs Ilm
2000 500
600
800
700
900
1000
T ( °C ) X Gr os = Ca/(Ca+Fe+Mg) of garnet
X Al m = F e /(Ca+Fe+Mg) of garnet
X P yr = Mg/(Ca+Fe+Mg) of garnet
Fig. 6
(a) S7 1828±6 03 04 1842±7
05 1822±9
26 1837±6
1854±3 06
17 1826±7
1832±5 07
25 1848±2
100µm
(b) S18
01 2507±9
07 1831±32
08 2572±7
2434±20 11 1868±25 12
1821±13 19 18
20 21 2402±8 1842±16
1816±18 100µm
Fig. 7
2400
0.44
(a) S7
0.40
upper intercept age: 1824±13Ma (MSWD = 0.78)
(b) S18
0.5
2600
upper intercept age: 1818±22Ma (MSWD = 0.36)
2200
2400 upper intercept age: 2547±47Ma (MSWD = 0.94)
0.4 2000
2000
0.36 207
weighted mean Pb/ Pb age: 1846±6Ma (MSWD = 8.4 , n=23) 2 07
1800
0.32
20 6
206
weighted mean Pb/ Pb age: 1823±8Ma (MSWD = 0.99 , n=14)
0.3 1600
lower intercept age: 1792±310 Ma (MSWD = 0.94)
0.2
0.28 3.5
4.5
5.5
6.5 207 Pb/ 2 3 5 U
7.5
8.5
9.5
2
4
6 207
8 Pb/ 2 3 5 U
10
12
14
Fig. 8
1070
Table 1. Representative compositions of garnets (cations are calculated based on 12 oxygens). Grt2
1071 1072 1073 1074
Grt3
Sample
S18 n=46
S25 n=34
S37 n=58
S18 n=3
SiO2
37.14
37.15
36.67 36.84
37.05 36.51
TiO2
0.02
0.02
0.04
0.04
Al2O3
21.09
21.71
21.46 20.94
21.27 21.27
FeO MnO MgO CaO
31.96 0.96 7.05 2.17
29.09 0.69 10.50 0.62
28.33 0.69 8.55 3.73
31.71 0.89 8.27 0.50
0.03 33.86 1.04 6.11 1.62
S25 n=5
S37 n=3 0.03 30.77 1.05 7.27 2.80
Na2O
0.02
0.02
0.01
0.03
0.03
0.04
K2O
0.01
0.01
0.01
0.02
0.02
0.01
Cr2O3
0.00
0.00
0.00
0.00
0.00
0.00
Total Si Ti Al
100.43 2.90 0.00 1.94
99.80 2.86 0.00 1.97
99.49 2.847 0.003 1.964
100.48 2.90 0.00 1.94
99.77 2.90 0.00 1.96
99.74 2.86 0.00 1.96
Fe2+
1.85
1.58
1.526 1.99
1.84
1.72
3+
Fe
0.26
0.32
0.340 0.26
0.25
0.32
Mn Mg Ca Na K Cr Total
0.06 0.82 0.18 0.00 0.00 0.00 8.02
0.05 1.20 0.05 0.00 0.00 0.00 8.03
0.045 0.990 0.310 0.002 0.001 0.00 8.03
0.07 0.72 0.14 0.00 0.00 0.00 8.02
0.06 0.96 0.04 0.00 0.00 0.00 8.02
0.07 0.85 0.23 0.01 0.00 0.00 8.03
XAlm
0.63
0.55
0.53
0.68
0.63
0.60
XPyr
0.28
0.42
0.34
0.25
0.33
0.30
XGros
0.06
0.02
0.11
0.05
0.01
0.08
XSps
0.02
0.02
0.02
0.02
0.02
0.02
XFe
0.69
0.57
0.61
0.74
0.66
0.67
XAlm = Fe2+/(Fe2+ + Mg + Mn + Ca); XPyr = Mg/(Fe2+ + Mg + Mn + Ca); XGros = Ca/(Fe2+ + Mg + Mn + Ca); XSps = Mn/(Fe2+ + Mg + Mn + Ca); XFe(g) = Fe2+/(Fe2+ + Mg). Ferric irons are determined according to the method of Droop (1987). Table 2. Representative compositions of orthopyroxene (cations are calculated based on 6 oxygens). Opx2 Sample
S18 n=9
Opx3 S25 n=6
S37 n=12
S25 n=3
SiO2
50.51
50.38
51.30
49.87
TiO2
0.07
0.06
0.06
0.06
Al2O3
3.23
5.08
2.32
5.00
FeO
29.20
24.47
25.91
23.09
50
MnO MgO CaO
0.16 17.44 0.11
0.13 20.41 0.01
0.16 20.14 0.17
0.09 21.15 0.01
Na2O
0.03
0.02
0.01
0.03
K2O
0.01
0.01
0.01
0.01
Cr2O3 Total Si Ti Al
0.01 100.76 1.92 0.00 0.14
0.00 100.57 1.88 0.00 0.22
0.02 100.10 1.93 0.00 0.10
0.02 99.32 1.87 0.00 0.22
Fe2+
0.92
0.74
0.79
0.68
3+
Fe
0.01
0.03
0.03
0.04
Mn Mg Ca Na K Total
0.01 0.99 0.00 0.00 0.00 4.00
0.00 1.13 0.00 0.00 0.00 4.00
0.01 1.13 0.01 0.00 0.00 4.00
0.00 1.18 0.00 0.00 0.00 4.00
0.52
0.61
0.59
0.63
XMg 1075 1076 1077 1078 1079
2+
XMg = Mg/(Mg + Fe ). Ferric irons are determined according to the method of Droop (1987).
Table 3. Representative compositions of biotite (cations are calculated based on 11 oxygens). Bt1 Sample
Bt2
S18 n=5
S25 n=3
SiO2
37.01
38.23 38.03
37.01 37.66
37.68 36.83
36.93 37.41
TiO2
3.82
4.41
4.43
3.76
3.92
Al2O3
16.12
16.07 16.31
15.92 16.06
16.15 15.82
15.77 15.78
FeO MnO MgO CaO Na2O
17.88 0.03 12.17 0.02 0.42
10.00 0.02 16.68 0.04 0.57
15.65 0.04 14.57 0.01 0.17
17.39 0.02 11.97 0.00 0.24
13.80 0.02 14.45 0.00 0.45
14.46 0.02 14.11 0.02 0.36
17.85 0.02 11.62 0.00 0.26
15.35 0.02 13.89 0.01 0.41
17.10 0.01 12.68 0.02 0.32
K2O
10.01
8.39
8.94
9.28
8.98
8.91
9.34
8.53
8.70
Cr2O3
0.01
0.05
0.03
0.02
0.02
0.03
0.03
0.05
0.04
Total Si Ti Al
97.48 2.75 0.21 1.41
94.45 2.79 0.24 1.38
95.77 2.81 0.11 1.42
96.28 2.76 0.25 1.40
95.53 2.78 0.23 1.40
95.50 2.79 0.21 1.41
96.24 2.76 0.25 1.40
94.87 2.76 0.22 1.39
95.52 2.80 0.20 1.39
Fe2+
1.11
0.61
0.97
1.09
0.85
0.89
1.12
0.96
1.07
3+
0.00
0.00
0.00
0.00
0.00
0.00
0.00
0.00
0.00
Fe
S37 n=3 2.03
S18 n=12
Bt3 S25 n=6
S37 n=11
4.09
51
S18 n=6 4.46
S25 n=6
S37 n=3 3.47
Mn Mg Ca Na K Total XFe 1080 1081 1082 1083
0.00 1.35 0.00 0.06 0.95 7.84
0.00 1.81 0.00 0.08 0.78 7.70
0.00 1.61 0.00 0.02 0.84 7.79
0.00 1.33 0.00 0.04 0.88 7.75
0.00 1.59 0.00 0.06 0.84 7.75
0.00 1.56 0.00 0.05 0.84 7.75
0.00 1.30 0.00 0.04 0.89 7.75
0.00 1.55 0.00 0.06 0.81 7.76
0.00 1.41 0.00 0.05 0.83 7.75
0.45
0.25
0.38
0.45
0.35
0.36
0.46
0.38
0.43
2+
2+
XFe = Fe /(Fe + Mg) Table 4. Representative compositions of plagioclase (cations are calculated based on 8 oxygens). Pl1
1084 1085 1086
Pl2
Sample
S18 n=3
S25 n=3
SiO2
58.41
TiO2
S37 n=3
Pl3
S18 n=18
S25 n=11
64.46 60.15
61.74
0.02
0.00
S18 n=6
S25 n=9
64.29 54.00
61.28
63.87 53.43
0.01
0.01
0.01
0.01
Al2O3
24.78
22.13 24.77
23.73
21.85 28.44
23.78
21.98 28.55
FeO MnO MgO CaO
0.53 0.02 0.00 7.75
0.13 0.00 0.01 3.43
0.32 0.00 0.00 7.28
0.07 0.01 0.01 6.17
0.05 0.00 0.00 3.33
0.12 0.01 0.01 11.87
0.15 0.01 0.00 6.24
0.23 0.01 0.00 3.52
0.13 0.00 0.01 12.61
Na2O
7.62
9.72
7.90
8.23
9.76
5.34
8.16
9.69
4.96
0.00
S37 n=9 0.01
S37 n=3 0.01
K2O
0.09
0.04
0.04
0.20
0.08
0.05
0.19
0.05
0.04
Cr2O3
0.00
0.02
0.00
0.01
0.01
0.01
0.00
0.01
0.00
Total Si Ti Al
99.23 2.64 0.00 1.32
99.94 2.84 0.00 1.15
100.44 2.68 0.00 1.30
100.17 2.74 0.00 1.24
99.39 2.85 0.00 1.14
99.87 2.45 0.00 1.52
99.81 2.73 0.00 1.25
99.37 2.84 0.00 1.15
99.75 2.43 0.00 1.53
Fe3+
0.02
0.00
0.01
0.00
0.00
0.00
0.01
0.01
0.00
Mn Mg Ca Na K Cr Total
0.00 0.00 0.38 0.67 0.01 0.00 5.03
0.00 0.00 0.16 0.83 0.00 0.00 5.00
0.00 0.00 0.35 0.68 0.00 0.00 5.02
0.00 0.00 0.29 0.71 0.01 0.00 5.00
0.00 0.00 0.16 0.84 0.00 0.00 5.00
0.00 0.00 0.58 0.47 0.00 0.00 5.03
0.00 0.00 0.30 0.71 0.01 0.00 5.00
0.00 0.00 0.17 0.83 0.00 0.00 5.00
0.00 0.00 0.61 0.44 0.00 0.00 5.02
XAn
0.36
0.16
0.34
0.29
0.16
0.55
0.29
0.17
0.58
Xab
0.64
0.83
0.66
0.70
0.84
0.45
0.70
0.83
0.41
XOr
0.00
0.00
0.00
0.01
0.00
0.00
0.01
0.00
0.00
Table 5. The P-T conditions of different metamorphic stages of the representative pelitic granulites of the Huashan Metamorphic Complex. Sample
Prograde stage (M1 ) 52
Peak stage (M2)
Retrograde stage
(M3) T (°C)
P (Kb ar)
Method
S18
S25
520– 530
S37
1087 1088 1089
4–5
Ti-in-bi otite geother momete r
T (° C)
P (Kb ar)
73 0 76 0 81 0 73 0 76 0 74 0
Meth od
8.6
GBP 68 Q 0 GOP Q 63 0 5 GBP 68 Q 0 GOP 57 Q 0 GBP 74 Q 0
7.3
GOP Q
7.2 6.8 7.8 7 6.8
81 0
T (° C)
P (Kb ar)
Metho d
5.1
GBPQ
Pseudo section 4.2
GBPQ
4.1
GOPQ
6.4
GBPQ
Table 6. SIMS U-Pb geochronological data of zircons separated from the representative pelitic granulites of the Huashan Metamorphic Complex. Spot
Content (ppm)
Th/ U
Istopic ratios 207
U
Th
Pb
S7-1
287
11
105
S7-2
1773
50
714
S7-3
337
15
124
S7-4
297
19
111
S7-5
149
21
57
S7-6
1898
45
732
S7-7
546
26
217
S7-8
291
11
108
S7-9
799
30
305
0.0 4 0.0 3 0.0 5 0.0 6 0.1 4 0.0 2 0.0 5 0.0 4 0.0 4
Pb/206 Pb
0.1113 0.1152 0.1117 0.1126 0.1114 0.1134 0.112 0.1114 0.1133
206
1σ 0.3 6 0.1 7 0.3 4 0.4 1 0.4 9 0.1 9 0.3 0.4 3 0.2 2 53
Age/(Ma)
Pb/23 U
1σ
0.3276
1.5
5.0278
0.3585
1.5
5.6959
0.327
1.5
5.0385
0.3309
1.5 3
5.1384
0.3315
1.5
5.089
0.3443
1.5
5.3812
0.353
1.5
5.4508
0.3308
1.5
5.0828
0.3391
1.5
5.2958
8
207
Pb/23 U
5
207
1σ 1.5 4 1.5 1 1.5 4 1.5 8 1.5 8 1.5 1 1.5 3 1.5 6 1.5 2
Pb/206 Pb
1 σ
1821
7
1883
3
1828
6
1842
7
1822
9
1854
3
1832
5
1823
8
1852
4
S7-1 0 S7-1 1 S7-1 2 S7-1 3 S7-1 4 S7-1 5 S7-1 6 S7-1 7 S7-1 8 S7-1 9 S7-2 0 S7-2 1 S7-2 2 S7-2 3 S7-2 4 S7-2 5 S7-2 6 S7-2 7 S7-2 8 S181 S182 S18-
157
5
58
1798
56
699
256
9
98
321
15
120
193
48
91
457
22
174
3003
195
117 4
237
10
88
144
69
77
1183
50
455
277
10
103
259
8
96
1841
97
699
264
9
99
278
11
103
2633
134
102 9
404
14
144
595
220
291
326
122
156
168
48
98
124
19
47
54
12
22
0.0 3 0.0 3 0.0 3 0.0 5 0.2 5 0.0 5 0.0 7 0.0 4 0.4 8 0.0 4 0.0 4 0.0 3 0.0 5 0.0 4 0.0 4 0.0 5 0.0 3 0.3 7 0.3 8 0.2 9 0.1 5 0.2
0.1114 0.1127 0.1121 0.111 0.123 0.1127 0.1133 0.1116 0.1422 0.1131 0.1114 0.1128 0.1139 0.111 0.1114 0.113 0.1123
0.5 1 0.1 8 0.4 1 0.4 8 0.6 9 0.4 1 0.1 6 0.3 8 0.4 8 0.2 6 0.4 9 0.3 6 0.1 3 0.3 6 0.3 7 0.1 4 0.3 6
0.3278
1.5 4
5.0327
0.3467
1.5
5.3887
0.3415
1.5 1
5.2769
0.3326
1.5
5.0922
0.3886
2.1 9
6.5924
0.3372
1.5
5.2394
0.3455
1.5
5.3985
0.331
1.5
5.0932
0.4181
1.5 1
8.2006
0.3418
1.5
5.3314
0.333
1.5
5.1126
0.3302
1.5
5.137
0.3361
1.5 4
5.2778
0.335
1.5
5.1266
0.3304
1.5
5.0734
0.3465
1.5 9
5.399
0.3188
1.5
4.9365
1.6 2 1.5 1 1.5 6 1.5 8 2.2 9 1.5 6 1.5 1 1.5 5 1.5 9 1.5 3 1.5 8 1.5 5 1.5 5 1.5 4 1.5 5 1.6 1.5 5 1.5 1 1.5 9
1822
9
1844
3
1834
7
1816
9
2001
1 2
1843
7
1853
3
1826
7
2255
8
1850
5
1822
9
1845
7
1862
2
1816
7
1822
7
1848
2
1837
6
2113
4
2102
9
9
0.1311
0.2
0.3927
1.5
7.0991
0.1303
0.5 1
0.3834
1.5 1
6.8877
0.4659
1.5
10.594 7
1.6
2507
0.3307
1.5
5.0458
1.6
1810
0.3416
1.5
5.2085
1.8
1809
0.1649 0.1107 0.1106
0.5 5 0.5 4 1.0
54
1 0 1
3 S184 S185 S186 S187 S188 S189 S1810 S1811 S1812 S1813 S1814 S1815 S1816 S1817 S1818 S1819 S1820 S1821 S1822 S1823 1090 1091 1092
25
9
10
58
13
22
85
8
32
13
5
6
218
84
142
178
71
117
99
8
38
226
73
123
28
6
10
215
82
144
48
10
19
114
44
73
251
121
172
42
10
16
74
13
29
71
14
28
627
5
321
45
8
18
81
7
31
51
9
20
3 0.3 6 0.2 2 0.1 0.3 6 0.3 8 0.4 0.0 8 0.3 2 0.2 2 0.3 8 0.2 1 0.3 8 0.4 8 0.2 5 0.1 7 0.2 0.0 1 0.1 7 0.0 9 0.1 7
0.1106 0.1109 0.1128 0.1119 0.1715 0.174 0.1114 0.1579 0.1142 0.1729 0.1107 0.1737 0.1803 0.1112 0.111 0.1113 0.155 0.1126 0.1127 0.1104
6 1.2 1 0.7 7 0.6 2 1.7 8 0.4 2 0.2 9 0.5 8 1.1 7 1.3 8 0.3 1 0.9 7 0.6 7 0.2 8 0.9 4 1.0 2 0.7 2 0.4 5 0.8 6 0.7 5 0.8 4
0.3329 0.3281 0.3308 0.3353 0.5065 0.5085 0.3387 0.4326 0.3061 0.5191 0.3379 0.4952 0.5207 0.3161 0.3333 0.3382 0.4424 0.3404 0.3326 0.3295
2 1.5 2 1.5 6 1.5 2 1.5 6 1.5 1 1.5 1.5 4 1.5 2 1.5 2 1.5 1.5 1 1.5 1 1.5 1.5 1 1.5 1 1.5 1 1.5 1.5 1 1.5 2 1.6 4
5.079 5.0182 5.1466 5.1753 11.973 3 12.199 9 5.2044 9.4193 4.8222 12.373 5.1584
1.8
11.858 1 12.941 9
1.6 5 1.5 3 1.7 8 1.8 3 1.6 7 1.5 7 1.7 4
4.8488 5.1026 5.1901 9.4533 5.2865
1810 1815 1845 1831
7
2596
5
1823 2434 1868 2586 1811 2593 2655 1820 1816 1821 2402 1842
1.7
1844
5.0137
1.8 5
1805
Table 7. Summary of metamorphic ages for the Taihua Metamorphic Complex.
9 2 2 1 4 1 1 3 2
2572
5.1707
The data with strikethrough are invalid.
55
5 1.9 4 1.7 4 1.6 4 2.3 6 1.5 7 1.5 3 1.6 4 1.9 2 2.0 5 1.5 4
1 1 2 0 2 5 5 1 8 1 1 5 1 7 1 8 1 3 8 1 6 1 4 1 5
Lushan
Wugang
Luoning
Huashan
Age (Ma)
Sample
Description
TW006/1
garnet-sillimanite gneiss
TWJ358/1
garnet gneissic granitoid
L15
amphibolite
L31
amphibolite
L40 L10 L56
amphibolite amphibolite amphibolite
L51
TTG
L54 L50
TTG gneissic granitoid
L57
amphibolite
L65
amphibolite
L66
amphibolite
HN804
amphibolite
YU19
amphibolite
YU21
amphibolite
YU23
amphibolite
04MC14
amphibolite
C21
amphibolite
C20
amphibolite
C23
metapelite
S2
amphibolite
1844 ± 66 1871 ± 14 1945 ± 25 1920 ± 12 1919 ± 8 1927 ± 7 1918 ± 5 1915 ± 14 1934 ± 7 1928 ± 5 1928 ± 6 1920 ± 17 1960 ± 26 1939 ± 19 1967 ± 32 1958 ± 32 1938 ± 9 1950 ± 20 1940 ± 10 1944 ± 5 1937 ± 11 1823 ± 4
S3
amphibolite
1890 19
S33
metapelite
1941 13
±
S51
amphibolite
1852 23
±
56
±
Method
Source
SHRIMP
Wan et al. (2006)
SHRIMP
Wan et al. (2006)
SIMS
Lu et al. (2013)
SIMS
Lu et al. (2013)
SIMS SIMS SIMS
Lu et al. (2013) Lu et al. (2015) Lu et al. (2015)
SIMS
Lu et al. (2015)
SIMS SIMS
Lu et al. (2015) Lu et al. (2015)
SIMS
Lu et al. (2014)
SIMS
Lu et al. (2014)
SIMS
Lu et al. (2014)
LA-ICP-MS
Jiang et al. (2011)
LA-ICP-MS
Jiang et al. (2011)
LA-ICP-MS
Jiang et al. (2011)
LA-ICP-MS
Jiang et al. (2011)
LA-ICP-MS
Diwu et al. (2014)
SIMS
Chen et al. (2015)
SIMS
Chen et al. (2015)
SIMS
Chen et al. (2015)
SIMS
Wang et al. (2012)
SIMS
Wang et al. (2012)
LA-ICP-MS
Wang et al. (2012)
LA-ICP-MS
Wang et al. (2012)
S24a
metapelite
1869 39
±
S25
metapelite
1848 20
±
S34
metapelite
1961 26
±
xql0912-2
gneissose pegmatitic granite
1866 19
±
xql0915-2
granitic veins
1881 24
±
THH08-62
granitic gneiss
1918 17
±
S1
amphibolite
S41
LA-ICP-MS
Wang et al. (2013)
LA-ICP-MS
Wang et al. (2013)
LA-ICP-MS
Wang et al. (2013)
LA-ICP-MS
Yu et al. (2013)
LA-ICP-MS
Yu et al. (2013)
LA-ICP-MS
Huang et al. (2013)
1846 ± 8
SIMS
Wang et al. (2014)
amphibolite
1866 17
±
SIMS
Wang et al. (2014)
08LF2
paragneiss
1928 15
±
LA-ICP-MS
Diwu et al. (2014)
S7
pelitic granite
1846 ± 6
SIMS
this study
S18
pelitic granite
1823 ± 8
SIMS
this study
1093 1094 1095
57
1096 1097
● Clockwise P–T–t paths were retrieved from the Mts. Huashan
1098
pelitic granulites.
1099
● SIMS U–Pb dating of metamorphic zircons reveal the
1100
metamorphic ages of 1.85–18.2 Ga.
1101
● The tectonothermal evolu(on of the TNCO started as early as
1102
~1.97 Ga and lasted as late as 1.80 Ga.
1103
● An eastward subduc(on model for the TNCO is suggested in
1104
this study.
1105 1106
58
S0301-9268(16)30387-4 http://dx.doi.org/10.1016/j.precamres.2016.12.008 PRECAM 4627
To appear in:
Precambrian Research
Received Date: Revised Date: Accepted Date:
14 September 2016 12 December 2016 25 December 2016
Please cite this article as: G-D. Wang, H.Y.C. Wang, H-X. Chen, J-S. Lu, B. Zhang, V. Tho Pham, J-J. Zhang, Q. Zhang, C-M. Wu, Metamorphic P–T–t paths of pelitic granulites of the Taihua metamorphic complex in the Mts. Huashan area and tectonothermal implications for the Palaeoproterozoic Trans-North China Orogen, Precambrian Research (2016), doi: http://dx.doi.org/10.1016/j.precamres.2016.12.008
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1
A revised original research manuscript submitted to Precambrian Research
2 3 4 5 6 7
Metamorphic P–T–t paths of pelitic granulites of the Taihua metamorphic complex in the Mts. Huashan area and tectonothermal implications for the Palaeoproterozoic Trans-North China Orogen
8 9 10
Guo-Dong Wang
a,b*
, Hao Y.C. Wang b, Hong-Xu Chen b, Jun-Sheng Lu c, Bo
Zhang d, Van Tho Pham b, Ji-Jun Zhang e, Qing Zhang f, Chun-Ming Wu b
11
a
Institute of Oceanology, Chinese Academy of Sciences, Qingdao 266071, China
12
b
College of Earth Science, University of Chinese Academy of Sciences, P.O. Box
13
4588, Beijing 100049, China
14
c
15
China
16
d
China Corporation of Coal Geology Engineering, Beijing 100040, China
17
e
Shaanxi Center of Geological Survey, Xi’an 710068, China
18
f
Institute of Geomechanics, Chinese Academy of Geological Sciences, Beijing 100081,
19
China
Institute of Geology and Geophysics, Chinese Academy of Sciences, Beijing 100029,
20
*
Corresponding author at: Institute of Oceanology, Chinese Academy of Sciences, Qingdao 266071, China. E-mail address: [email protected] (G.-D. Wang). 1
21
22
ABSTRACT
23
Metamorphic evolution and geochronology of pelitic granulites were reported
24
for the first time in the Taihua metamorphic complex, Mts. Huashan area, southern
25
segment of the Trans-North China Orogen (TNCO). Three generations of
26
metamorphic mineral assemblages are recognized: (1) the prograde metamorphic
27
mineral assemblages (M1) are represented by mineral inclusions within the garnet
28
porphyroblasts; (2) the metamorphic peak assemblage (M2) are the garnet
29
porphyroblasts and minerals in the matrix (biotite + orthopyroxene + plagioclase +
30
quartz +
31
metamorphic mineral assemblages (M3) are represented by the symplectic
32
assemblages around the garnet porphyroblasts, resulted from decomposition reactions
33
between garnet rims and neighboring minerals in the matrix. Calculated by both
34
conventional thermobarometry and pseudosection modeling in the NCKFMASHT
35
system using the Perple_X technique, the P–T conditions of these three metamorphic
36
stages are constrained to be of 4–5 kbar/520–530 °C for the M1 stage, 6.8–8.6
37
kbar/730–810 °C for the M2 stage and 4.1–6.4 kbar/570–740 °C for the M3 stage,
38
respectively. The derived clockwise P–T paths imply that the Mts. Huashan terrane
39
involved in the subduction and subsequent collision between the Eastern and Western
40
Blocks of the North China Craton (NCC) along the Palaeoproterozoic Tran-North
41
China Orogen (TNCO). High resolution SIMS U–Pb dating of metamorphic zircons
42
reveals the metamorphic ages of 1.85–1.82 Ga. Combined with geochronological data
K-feldspar + ilmenite + zircon + magnetite); and (3) the retrograde
2
43
from the literature, it is concluded that the tectonothermal evolution between the
44
Eastern and Western Blocks started as early as ~1.97 Ga and lasted as late as 1.80 Ga.
45
Furthermore, the eastern Taihua complex records older metamorphic ages and higher
46
peak metamorphic pressures than those of the western Taihua complex, possibly
47
suggesting an eastward subduction model for the TNCO.
48
Keywords: Pelitic
49
path; North China Craton.
granulites; Taihua metamorphic complex; Metamorphic P–T–t
50 51 52 53 54 55 56 57 58 59 60 61 62 63 64
3
65 66
1. Introduction
67
Extensive studies of metamorphic P–T paths on various metamorphic terranes
68
worldwide indicate that different P–T paths are generally closely related to specific
69
tectonic environments or geodynamic processes the terranes underwent (England and
70
Richardson, 1977; England and Thompson, 1984; Bohlen, 1987, 1991; Harley, 1989;
71
Lu, 1991; Spear, 1992; Brown, 1993, 2009; Zhao et al., 1998, 2000a). The
72
anticlockwise P–T paths, especially for those containing near-isobaric cooling (IBC)
73
segments, are usually suggested to be the products of magmatic intrusion and
74
underplating in the regional setting of continental magmatic arc, hot spot or
75
continental rift (Sandiford and Powell, 1986; Bohlen, 1987, 1991; Harley, 1989; Lu,
76
1991; Zhao et al., 1998, 2000a). The clockwise P–T paths, especially for those
77
containing nearly isothermal decompression (ITD) segments, are generally interpreted
78
to be the results of subduction to continental collision followed by rapid uplift or
79
exhumation (England and Thompson, 1984; Bohlen, 1991; Lu, 1991; Brown, 1993;
80
Zhao et al., 2000a). To derive metamorphic P–T conditions and metamorphic P–T
81
paths, there are two general ways, i.e., thermobarometry and thermodynamic
82
pseudosection modeling. Thermobarometry is a conventional method and is based on
83
thermodynamic equilibrium preserved in the mineral assemblages. Thermodynamic
84
pseudosection modeling (e.g., Powell and Holland, 2008) is a forward calculation
85
method in determining the mineral assemblages, mineral modes and chemical
4
86
compositions of the minerals involved at different P–T conditions, based on the
87
assumption of closed chemical system during the metamorphic process.
88
A number of investigations on the metamorphic P–T paths and geochronology
89
of the metamorphic terranes distributed within the Palaeoproterozoic Trans-North
90
China Orogen (TNCO) (Zhao et al., 1998, 2000a, 2001a, 2005, 2012) have been
91
carried out in the last two decades (e.g., Zhai et al., 1993; Mei, 1994; Liu, 1996, 1997;
92
Guo et al., 1998, 2002, 2005; Wang et al., 1991; Zhao et al., 1999, 2000b, 2001b,
93
2002, 2007, 2010b; Liu et al., 2004, 2006, 2007; Kröner et al., 2005, 2006; O’Brien et
94
al., 2005; Faure et al., 2007; Trap et al., 2007, 2008, 2009a; Xiao et al., 2011; Lu et al.,
95
2013, 2014; Qian et al., 2013, 2015, 2016; Wang et al., 2014; Chen et al., 2015). Most
96
of these metamorphic terranes recorded clockwise P–T paths involving nearly ITD
97
segments, which were generally interpreted as the results of the subduction and
98
collision between the Eastern Block and the Western Block along the N–S-striking
99
TNCO at ~1.85 Ga (Fig. 1a) (Zhao et al., 1998, 2005, 2012).
100
The Taihua metamorphic complex, exposing in the southernmost margin of the
101
TNCO, experienced high-amphibolite- to granulite-facies metamorphism (Kang et al.,
102
1988; Qi, 1991, 1992; Chen et al., 1997; Zhou et al., 1997, 1998; Wang et al., 2014)
103
and provides a perfect window to explore the tectonothermal evolution of the TNCO.
104
Researches on metamorphism were carried out on amphibolites from the Taihua
105
complex (Jiang et al., 2011; Lu et al., 2013, 2014; Wang et al., 2014; Chen et al.,
106
2015), however, no metamorphic evolution of pelitic granulite has been studied by
107
now, which restricts our whole understanding on the tectonothermal evolution of the
5
108
southern margin of the TNCO in the Paleoproterozoic. This is because pelitic graulites
109
are usually deemed as markers for recognizing Precambrian subduction/collision belts,
110
on account of that the sedimentary protoliths of pelitic granulites could only be
111
brought down to the middle/lower crustal levels and experienced granulite-facies
112
metamorphism by subduction/collison process (Zhao and Zhai, 2013). In this paper,
113
we present detailed petrology, mineral chemistry and P–T conditions of
114
metamorphism estimated by both conventional thermobarometry and pseudosection
115
modeling for the pelitic granulites, collected from the Taihua Group in the Mts.
116
Huashan terrane, and reconstruct the P–T paths of these rocks to reveal the
117
tectonothermal history of the southernmost terminal of the TNCO in the
118
Paleoproterozoic.
119
2. Regional setting
120
The Taihua metamorphic complex, termed as the Taihua Group in the traditional
121
Chinese literature, is located in the southernmost margin of the TNCO. It is mainly
122
consisting of the Mts. Huashan terrane in the northwest, the Xiaoshan and Luoning
123
terranes in the middle and the Lushan and Wugang terranes in the southeast. In the
124
last few years, some studies were carried out on the geochronology and metamorphic
125
evolution of these terranes (e.g. Wan et al., 2006;Liu et al., 2009; Diwu et al., 2010,
126
2014; Huang et al., 2010, 2012, 2013; Lu et al., 2013, 2014; Wang et al., 2012, 2013,
127
2014; Chen et al., 2015). In the Luoning terrane, Jiang et al. (2011) and Chen et al.
128
(2015) proposed that the amphibolites, whose protolith age was 2.34–2.30 Ga,
129
recorded clockwise P–T paths containing isothermal decompression (ITD) segments,
6
130
and the metamorphism occurred during 1.97–1.94 Ga according to SIMS and
131
LA-ICP-MS U–Pb dating of metamorphic zircons. Additionally, Huang et al. (2012)
132
reported two magmatic events (2.32–2.30 Ga and 2.19–2.07 Ga) of the TTG gneisses
133
in this area. Chen et al. (2016) further found that four episodes of crustal growth and /
134
or reworking in this region have occurred at 2.85–2.72 Ga, 2.54–2.48 Ga, 2.35–2.30
135
Ga and 2.2–2.0 Ga, respectively, possibly to connect with the subduction–collision
136
between the Eastern and Western Blocks along the TNCO. In the Lushan and Wugang
137
terranes, the protolith ages of the TTG gneisses and amphibolites were recognized as
138
2.85–2.72 Ga (Liu et al., 2009; Diwu et al., 2010; Huang et al., 2010) followed by a
139
metamorphic age of 1.87–1.84 Ga (Wan et al., 2006;Yang,2008). Based on detailed
140
studies on the amphibolites from both blocks, Lu et al. (2013, 2014) proposed that
141
both of the Lushan and the Wugang terranes recorded clockwise P–T paths including
142
ITD segments and the upper amphibolite facies metamorphism occurred at ca.
143
1.95–1.86 Ga and 1.96–1.92 Ga, respectively.
144
Exposed on the northern and southern slopes of the Mts. Huashan in the
145
Shan’anxi and Henan Provinces (Fig. 1b), the Huashan metamorphic complex has
146
attracted many attentions in recent years. In summary, based on U–Pb dating of
147
zircons and
148
three obvious episodes of magmatism (~2.5 Ga, ~2.3 Ga and 1.87–1.80 Ga) and one
149
episode of metamorphism (1.80–1.96 Ga) were identified in this region (Wang et al.,
150
2012, 2013, 2014, 2016; Huang et al., 2013; Yu et al., 2013). Our previous studies on
151
petrology, mineral chemistry, geochronology and metamorphic P–T paths of the
40
Ar/39Ar dating of amphiboles from the Huashan metamorphic complex,
7
152
amphibolites from this region indicate that the Mts. Huashan metamorphic complex
153
experienced
154
Paleoproterozoic. Clockwise P–T paths involving ITD segments were retrieved from
155
these amphibolites (Wang et al., 2014), which probably imply that the
156
Paleoproterozoic collision occurred between the Eastern and Western Blocks of the
157
NCC along the TNCO.
high-amphibolite
to
granulite
facies
metamorphism
in
the
158
The garnet-bearing pelitic granulites were not found at the outcrop but were
159
collected from the mining sites, which were confirmed to belonging to the Taihua
160
complex by field observation. Sampling locations of these samples are shown in
161
Fig.1b. Petrography and metamorphic researches were performed on three
162
representative garnet-bearing pelitic granulite samples (S18, S25 and S37), and U–Pb
163
dating of metamorphic zircons were carried out on two samples (S7 and S18).
164
3. Petrography and metamorphic stages
165
Most of the pelitic granulites show retrograde “white-eye socket” texture (Fig.
166
2), which was originally named by Ma and Wang (1994) in mafic granulites to
167
explain the retrograde symplectic assemblages surrounding garnet porphyroblasts. On
168
the basis of micropetrographic observation, three stages of metamorphic mineral
169
assemblages were recognized in these granulites, designated as the prograde mineral
170
assemblages (M1), the peak mineral assemblages (M2) and the retrograde mineral
171
assemblages (M3), respectively. Detailed microstructures and reaction relationships
172
are described below. The symbols of minerals used in this study are after Whitney and
173
Evans (2010).
8
174
3.1 The prograde mineral assemblages (M1)
175
The prograde metamorphic mineral assemblages (M1) are preserved as mineral
176
inclusions within the garnet porphyroblasts (Fig. 2a–d), which are mainly composed
177
of biotite (Bt1) + plagioclase (Pl1) + quartz (Qz1) ± ilmenite (Ilm1). These
178
inclusion-type minerals are distributed randomly within the garnets, representing the
179
remnants of the prograde assemblages. It is noted that some inclusion-like minerals
180
distributed along the fractures within the garnets are not actually inclusion minerals,
181
but were formed within the garnet interiors during the retrograde metamorphic stage.
182
Only the inclusion minerals not cut by late fractures within the garnets and showing
183
no Fe–Mg re-exchange features with the surrounding garnet interiors are ascribed to
184
the prograde stage.
185
3.2 The metamorphic peak assemblages (M2)
186
The metamorphic peak mineral assemblages (M2) are represented by the
187
coarse-grained garnet porphyroblasts (Grt2) and matrix minerals biotite (Bt2),
188
orthopyroxene (Opx2), plagioclase (Pl2), quartz (Qz2), with minor K-feldspar (Kfs2),
189
ilmenite (Ilm2), zircon (Zr2) and magnetite (Mag2) (Fig. 2a–d). The straight contacts
190
and nearly homogeneous chemical compositions, described below, of these minerals
191
suggest that thermodynamic equilibrium had been approached during the
192
metamorphic peak stage. It is inferred that the metamorphic peak assemblages (M2)
193
were formed from the prograde assemblages (M1) possibly by the following reaction:
194 195
Bt1 + Pl1 ± Ilm1 → Grt2 +Bt2 + Opx2 + Pl2 + Kfs2 ± Mag2 ± Ilm2 (M1)
(M2) 9
196
3.3 The retrograde mineral assemblages (M3)
197
The retrograde metamorphic assemblages are characterized by the formation of
198
symplectic assemblages around the garnet porphyroblasts, resulted from the
199
decomposition reactions between the garnet rims and the neighboring minerals in the
200
matrix. Such kind of reaction textures, nicknamed as “white-eye socket” texture,
201
represent typical decompression and decomposition reactions in mafic granulites and
202
amphibolites within the Trans-North China Orogen (e.g., Wang et al., 1991; Liu, 1996;
203
Guo et al., 1998, 2002; Zhao et al., 2000b, 2001b, 2010a; O’Brien et al., 2005; Xiao et
204
al., 2011; Lu et al., 2013, 2014; Wang et al., 2014; Chen et al., 2015). The symplectic
205
mineral assemblages are mainly comprised of biotite (Bt3) + plagioclase (Pl3) + quartz
206
(Qz3) ± orthopyroxene (Opx3) around the embayed garnet porphyroblasts (Fig. 2a–d),
207
suggesting the following possible reaction:
208 209 210
Grt2 (rim) + Bt2 + Pl2 → Grt3 + Bt3 + Pl3 ± Opx3 (M2)
(M3)
4. Mineral chemistry
211
X-ray compositional mapping of the garnets (Fig. 3) as well as mineral chemical
212
compositions of the pelitic granulite samples S18, S25 and S37 were analyzed using
213
the JOEL JXA 8230 electron microprobe equipped at the School of Resources and
214
Environment Engineering, Hefei University of Technology, China. The analytical
215
conditions were 15 kV accelerating voltage, a beam current of 20 nA with an electron
216
beam size of 5 µm and 10–20 s counting time. Natural and synthetic minerals were
217
used as standards, and the program ZAF was used for matrix correction. For each kind 10
218
of mineral of any generation, at least three grains were analyzed and at least three spot
219
analyses were performed for each grain. Representative mean chemical compositions
220
of the minerals are presented in Tables 1–4. The detailed compositional features of the
221
minerals are described below.
222
4.1. Garnet
223
The bell-shaped XMn and Fe# [=Fe/(Fe+Mg)] zoning profiles of the garnet in
224
metapelites were interpreted as typical prograde growth zonation of metapelitic garnet
225
(Spear et al., 1990; Spear and Florence, 1992). Sometimes the bell-shaped profiles
226
could hardly be preserved in high-grade metamorphic rocks, if Fe-Mg re-exchange
227
occurred during slow cooling after the metamorphic peak, led to increase of Fe# value
228
in the garnet rim (Spear and Florence, 1992). Simultaneous increasing of the Fe# and
229
XMn values of the garnet rim suggests that the garnet rim experienced net transfer and
230
Fe-Mg re-exchange reactions, lead to formation of the symplectite (Kohn and Spear,
231
2000). The X-ray mapping analyses (Fig. 3a–c) of the garnet porphyroblasts show
232
homogeneous features with no or weak prograde profiles from the core to the mantle
233
domains and weak Fe-Mg re-exchange in the outer rims, which suggest that
234
thermodynamic equilibrium had possibly been achieved within the peak mineral
235
assemblages at the metamorphic peak stage and re-equilibrium occurred during the
236
retrograde stage. All the garnets are dominated by almandine (XAlm = 0.53–0.68),
237
pyrope (XPyr = 0.25–0.42) with minor grossular (XGrs = 0.01–0.11) and spessartine
238
(XSps = 0.02) components (Table 1). Consistent with the X-ray mapping analyses, the
239
rim-core-rim analytical chemical profiles of these garnets (Fig. 4a–c) also show no or
11
240
weak compositional zonation from the core to the mantle domains. Slight increases of
241
XAlm (from 0.53–0.63 to 0.60–0.68), Fe# (from 0.57–0.69 to 0.66–0.74) and a weak
242
increase of XGrs (from 0.02–0.11 to 0.01–0.08) were observed towards the rims (Fig.
243
4a–c), indicating re-equilibrium occurred during the retrograde metamorphic stage.
244
No obvious increase of spessartine component corresponding to the breakdown of
245
garnet rims (Kohn and Spear, 2000) was observed, probably because of their low
246
spessartine contents (XSps = 0.02).
247
4.2. Orthopyroxene
248
Orthopyroxene is subhedral or anhedral, with variable grain size in the matrix
249
(Opx2) or occurs as intergrowth mineral with the matrix biotite. Symplectic
250
orthopyroxene (Opx3) is only observed in sample S25. The matrix orthopyroxene
251
(Opx2) is richer in FeO (24.47–29.20 wt%) and poorer in MgO (17.44–20.41 wt%)
252
components with XMg [=Mg/(Fe+Mg)] values varying between 0.52–0.61. The
253
symplectic orthopyroxene (Opx3) has lower FeO (23.09 wt%) and higher MgO (21.15
254
wt%) contents with XMg = 0.63 (Table 2).
255
4.3. Biotite
256
Three textural types of biotite were analyzed in the pelitic granulites: the
257
inclusion-type biotite (Bt1) within the garnet porphyroblast, matrix-type biotite (Bt2)
258
intergrown with orthopyroxene in the matrix and retrograde biotite (Bt3) intergrown
259
with plagioclase and quartz in the symplectite. These three types of biotite display
260
slight differences in FeO and TiO2 components (Table 3). The Bt1 has FeO contents of
261
10.00–17.88 wt% and TiO2 contents of 2.03–4.41 wt%. In samples S18 and S37, the
12
262
Bt2 have lower FeO contents (14.46–17.39 wt%) and higher TiO2 contents (3.76–4.43
263
wt%) than those of Bt1. In sample S25, the Bt2 has higher FeO contents (13.80 wt%)
264
and lower TiO2 contents (4.09 wt%) than those of Bt1. In all these samples, the Bt3 is
265
richer in FeO (15.35–17.85 wt%) and poorer in TiO2 (3.47–4.46 wt%) contents than
266
those of the Bt2.
267
4.4. Plagioclase
268
Representative chemical compositions of three types of plagioclase are
269
summarized in Table 4: the inclusion-type plagioclase (Pl1) within the garnet
270
porphyroblast, plagioclase in the matrix (Pl2) and retrograde plagioclase (Pl3) formed
271
coeval to symplectic biotite and quartz. Most of the plagioclase grains are chemically
272
homogeneous, but chemical diversities exist for different plagioclase crystals either
273
among different samples or in the different assemblages formed at different
274
metamorphic stages within one sample.
275
In sample S18, the Pl2 and Pl3 contain similar anorthite contents (An = 29), but
276
lower than that of the Pl1 (An = 36). In sample S25, the anorthite contents in Pl1 (An =
277
16) and Pl2 (An = 16) are slightly lower than the Pl3 (An = 17). In sample S37, the
278
anorthite content increases from the Pl1 (An = 34) to the Pl2 (An = 55). The Pl3 has the
279
highest anorthite content (An = 58). The increases of anorthite contents from Pl2 to Pl3
280
in S25 and S37 suggest that the breakdown of garnet rims supplied additional CaO
281
content to the newly formed Pl3 during the retrograde stage.
282
5. Metamorphic P–T conditions
283
5.1. Geothermobarometry 13
284
Present available geothermometers and geobarometers were employed to
285
determine the P–T conditions of the Huashan pelitic granulites. However, there are no
286
suitable geobarometers for the prograde mineral assemblages (Bt1 + Pl1 + Qz1 ± Ilm1).
287
The Ti-in-biotite geothermometer for TiO2-saturated metapelites proposed by Wu and
288
Chen (2015) is appropriate with a random error of ca. ±65 °C. However, only
289
inclusion-type biotite (Bt1) in S37 contains suitable XTi (0.11), which is located in the
290
compositional limits of biotite (XTi = 0.02–0.14) for this geothemometer. A
291
temperature of 520–530 °C was determined by this geothemometer at a given pressure
292
of 4–6 kbar. The metamorphic peak and retrograde P–T conditions of these pelitic
293
granulites were determined by applying the garnet–biotite (GB) geothermometer
294
(Holdaway, 2000) combined with the garnet–biotite–plagioclase–quartz (GBPQ)
295
geobarometer (Wu et al., 2004) and the garnet–orthopyroxene–plagioclase–quartz
296
(GOPQ) geothermobarometer (Lal et al., 1993). It is noteworthy that Fe-Mg
297
re-exchanging during cooling after the metamorphic peak might occur between the
298
matrix-type ferromagnesian minerals, especially for the contacting biotite,
299
orthopyroxene and garnet. Therefore, the compositions of isolated garnet, biotite and
300
orthopyroxene were employed to calculate the peak P–T conditions. It is noted that
301
although retrograde zonings were observed on the garnet rims, thermodynamic
302
equilibrium might not have been achieved between the garnet rims and the symplectic
303
minerals (Wu et al., 2014). Therefore, accuracy of the retrograde P–T conditions
304
obtained here need to be used with caution.
305
The computed P–T conditions of the three metamorphic stages of the pelitic
14
306
granulites are listed in Table 5.
307
5.1.1 Sample S18
308
The metamorphic peak (M2) P–T conditions were estimated to be 7.2
309
kbar/730 °C by the GB geothermometer coupled with the GBPQ geobarometer.
310
Similar peak (M2) P–T conditions of 6.8 kbar/760 °C were obtained by the GOPQ
311
geothermobarometers. The retrograde assemblages (M3) recorded P–T conditions of
312
5.1 kbar/680 °C determined by GB geothermometer coupled with the GBPQ
313
geobarometer. Therefore, a clockwise P–T path was retrieved (Fig. 5a).
314
5.1.2 Sample S25
315
The M2 P–T conditions of this sample were determined to be 7.0 kbar/730 °C by
316
GB geothermometer combined with GBPQ geobarometer or 6.8 kbar/760 °C obtained
317
by the GOPQ geothermobarometers, respectively. The M3 assemblages recorded P–T
318
conditions of 4.2 kbar/680 °C determined by the GB geothermometer coupled with
319
the
320
geothermobarometers, respectively. Although the grossularite content of garnet (Xgrs
321
= 1–2%) and anorthite content of plagioclase (An = 16–17) in these two metamorphic
322
stages were lower than the recommended lower limits (Xgrs > 3%, An > 17) for the
323
GBPQ geobarometer as given in Wu et al. (2004), it still gave similar results
324
compared with the results obtained by the GOPQ geothermobarometers. Therefore, a
325
clockwise P–T path was also reconstructed (Fig. 5b).
326
5.1.3 Sample S37
327
GBPQ
geobarometer
or
4.1
kbar/570
°C
obtained
by the
GOPQ
The M2 P–T conditions were calculated as 8.6 kbar/740 °C by the GB
15
328
geothermometer coupled with the GBPQ geobarometer or 7.3 kbar/810 °C by the
329
GOPQ geothermobarometers. The M3 P–T conditions were estimated as 6.4
330
kbar/740 °C by the GB geothermometer in concert with the GBPQ geobarometer. A
331
clockwise P–T path was also reconstructed (Fig. 5c).
332
5.2. Pseudosection modeling
333
Sometimes people may make mistakes in distinguishing different mineral
334
assemblages formed at different metamorphic stages in medium to high grade
335
metamorphic rocks (e.g., Nicollet and Goncalves, 2005; Vernon et al., 2008), which
336
may result in wrong conclusions for the regional tectonic evolution. In addition,
337
thermodynamic equilibrium might not have been achieved between the garnet rims
338
and the symplectic minerals (Wu et al., 2014). To confirm the P–T conditions
339
obtained by conventional geothermobarometers, we performed a P–T pseudosection
340
on sample S18 with the Perple_X computer program (Connolly, 2005).
341
5.2.1 P–T pseudosection modeling
342
The P–T pseudosection was calculated with the Perple_X computer program
343
package (Connolly, 2005; Version of 6.68) using the internally consistent
344
thermodynamic dataset of Holland and Powell (1998, updated 2002). The bulk-rock
345
composition of the chosen sample was analyzed by X-ray fluorescence spectrometry
346
(XRF) at the Institute of Geology and Geophysics, Chinese Academy of Sciences,
347
Beijing. The above studies on petrography and mineral chemistry suggest that the
348
amounts of Mn and Fe3+ cations in the minerals are negligible; therefore the MnO and
349
Fe2O3 contents were ignored in the pseudosection calculation. On the contrary, the
16
350
noticeable Ti amount in biotite demonstrates that the TiO2 amount in bulk-rock
351
composition could affect the stable region of biotite in pseudosection constructions in
352
metapelite (Peterson et al., 1991; Dooley et al., 1996). So the P–T pseudosection was
353
calculated
354
(NCKFMASHT) system. Apatite is present in this sample, which contains most of the
355
P2O5 contents in the bulk-rock composition. So we deducted the CaO content,
356
constituent of apatite, from the bulk-rock composition according to the standard
357
molecular formula of apatite (Ca: P = 5:3, in mol). As we know, there is a great
358
variety in the FeO/Fe2O3 ratio among metapelites. Due to the high Fe3+ contents in the
359
garnet porphyroblast and the presence of magnetite in the matrix mineral assemblages,
360
83% of total Fe2O3 (Fe2O3T) is assumed to be the FeO, which means a reasonable high
361
Fe2O3 content of total Fe2O3 content of the rock. Besides, the loss on ignition (LOI)
362
was employed as the H2O content. With these reasonable assumptions, the final
363
effective bulk-rock composition of the sample (in wt%) is as follows: SiO2 = 52.64,
364
TiO2 = 0.85, Al2O3 = 17.69, FeO = 9.93, MgO = 5.87, CaO = 3.15, Na2O = 3.94, K2O
365
= 2.38 and H2O = 0.56.
in
the
Na2O–CaO–K2O–FeO–MgO–Al2O3–SiO2–H2O–TiO2
366
The minerals involved in the pseudosection construction include: garnet (Grt),
367
plagioclase (Pl), orthopyroxene (Opx), biotite (Bt), cordierite (Crd), K-feldspar (Kfs),
368
ilmenite
369
activity-composition (a-X) models used in the pseudosection calculation are those of
370
garnet (White et al., 2007), plagioclase (Newton et al., 1980), orthopyroxene (Holland
371
and Powell, 1998), biotite (Tajcmanová et al., 2009), cordierite (Holland and Powell,
(Ilm),
rutile
(Rt),
quartz
(Qz)
17
and
silicate
melt
(Liq).
The
372
1998), K-feldspar (Waldbaum and Thompson, 1968), ilmenite (White et al., 2000)
373
and melt (White et al., 2007). Rutile and quartz are essentially pure end-member
374
phases.
375
5.2.2 P–T pseudosection
376
The P–T pseudosection computed in the P–T range of 2–10 kbar/500–1000 °C in
377
the NCKFMASHT system for the pelitic granulite (S18) is shown in Fig. 6. Biotite,
378
orthopyroxene, plagioclase and K-feldspar are stable and are present in most of the
379
pseudosection regions. Garnet is a stable phase in high pressure fields with the
380
garnet-in line starting from 3 kbar/500 °C to 8.5 kbar/1000 °C. Quartz appears in most
381
fields with the quartz-out line vertically lying from 800 °C at 2 kbar to 920 °C at 10
382
kbar. Cordierite is stable only in low pressure fields (<4 kbar), and rutile is stable in
383
high pressure and low temperature fields (P>7 kbar, T<560 °C). The solidus curve
384
vertically lies from 790 °C at 2 kbar to 890 °C at 10 kbar, which is consistent with no
385
partial melting in this rock (i.e., it was a closed system).
386
It’s also difficult to estimate the prograde P–T conditions in the pseudosection
387
because no prograde chemical profiles were preserved in garnet porphyroblasts.
388
However, there must be a prograde stage for metapelite because the mud was brought
389
down to the middle/lower crustal levels and experienced granulite-facies
390
metamorphism.
391
The homogeneous chemical composition of the garnet porphyroblast from the
392
core to the mantle in sample S18, formed during the metamorphic peak stage, was
393
normalized as XAlm = 0.65, XPyr = 0.29 and Xgrs = 0.06 after removing the XSps
18
394
content. The isopleths of XAlm (ranging from 0.65 to 0.70), XPyr (ranging from 0.25 to
395
0.29) and Xgrs (ranging from 0.05 to 0.06) in garnet were shown in the P–T
396
pseudosection (Fig. 6). The P–T conditions of the metamorphic peak was constrained
397
as 7.8 kbar/810 °C by pseudosection, which is a little higher than the results of
398
6.8–7.2 kbar/730–760 °C estimated by conventional geothermobarometers. This is
399
probably due to the effect of Fe-Mg diffusion between ferromagnesian minerals after
400
the metamorphic peak stage, although the compositions of isolated garnet, biotite and
401
orthopyroxene were employed to calculate the peak P–T conditions. The
402
corresponding peak mineral assemblage is Opx + Grt + Pl + Bt + Kfs + Qz, which
403
agrees with the peak mineral assemblage we observed under microscope. Therefore, a
404
prograde reaction (dashed line in Fig. 6) from Opx + Grt + Pl + Bt + Kfs + Ilm + Qz
405
(M1) to Opx + Grt + Pl + Bt + Kfs + Qz (M2) was inferred. No Opx and Kfs were
406
observed in the inclusion-type mineral assemblages (M1, Bt + Pl + Ilm + Qz) in this
407
sample, probably suggests that no Opx and Kfs survived as inclusions in the garnet
408
during the prograde stage.
409
Analogously, composition of the garnet rim was normalized as XAlm = 0.70, XPyr
410
= 0.25 and Xgrs = 0.05 according to EPMA data. The corresponding isopleths
411
constrain the retrograde (M3) P–T conditions to be 5.0 kbar/630 °C (Fig. 6), which
412
was also similar to those (5.0 kbar/680 °C) estimated by conventional
413
geothermobarometers. So a clockwise P–T path was also obtained for the pelitic
414
granulite in the P–T pseudosection modeling.
415
5.3. Metamorphic P–T paths 19
416
The metamorphic P–T conditions of the M1, M2 and M3 assemblages were
417
estimated by both conventional geothermobarometers and P–T pseudosection
418
modeling. The prograde (M1) metamorphic P–T conditions were proposed as
419
520–530 °C/4–6 kbar (assumed). The metamorphic peak (M2) P–T conditions were
420
determined as 6.8–8.6 kbar/730–810 °C, belonging to the transition zone of high
421
amphibolite to granulite facies and intermediate P/T metamorphic facies series
422
(Miyashiro, 1961; Spear, 1993, pp. 15–22). The retrograde (M3) P–T conditions were
423
estimated as 4.1–6.4 kbar/570–740 °C. Therefore, clockwise P–T paths were
424
constructed for these pelitic granulite samples.
425
6. Geochronology
426
6.1. Analytical methods
427
Zircon grains collected from Samples S7 and S18 were mounted in epoxy
428
mounts with zircon standard Plešovice (Sláma et al., 2008) and Qinghu (Li et al.,
429
2009), which were then polished to section the crystals in half for analyses. All the
430
zircons were taken micrographs of reflected and transmitted light as well as
431
cathodoluminescence (CL) images to reveal their internal structures. The mount was
432
then vacuum-coated with high-purity gold prior to secondary ion mass spectrometry
433
(SIMS) analysis. Analyses of U, Th and Pb were performed using the Cameca
434
IMS-1280 SIMS mass spectrometer equipped at the Institute of Geology and
435
Geophysics, Chinese Academy of Sciences, Beijing. Detailed analytical procedures
436
were described by Li et al. (2009). The analytical spot was an ellipsoid with size of
437
about 30µm×20µm. Non-radiogenic 204Pb was used to correct measured compositions
20
438
for common Pb. The average of present-day crustal composition (Stacey and Kramers,
439
1975) was used for the common Pb assuming that the common Pb is largely surface
440
contamination introduced during the preparation of samples. The analytical results are
441
listed in Table 6. The uncertainties on individual analyses are reported at the 1σ level
442
and the mean ages for U/Pb (Pb/Pb) analyses are quoted with the 95% confidence
443
interval. Data reduction was carried out using the Isoplot/Ex v. 3.75 program (Ludwig,
444
2003).
445
6.2. Analytical results
446
Zircon grains from sample S7 are stubby columnar and round in shape and about
447
100–200 µm in length. Most of the zircons show homogeneous texture with low
448
luminescence in cathodoluminescence (CL) images (Fig. 7a) displaying features of
449
possible metamorphic origin. Some round grains show cores with weak magmatic
450
rhythmic textures, which are considered as detrital zircons. Twenty-eight U–Pb spot
451
analyses were obtained from 22 zircon grains. The U and Th contents and the U/Th
452
ratios of the 23 valid analytical spots performed on the metamorphic zircon grains are
453
in the range of 149–3003 ppm, 5–195 ppm and 0.02–0.1, respectively. All these
454
analytical spots are distributed on or close to the concordia and yield an upper
455
intercept age of 1824±13 Ma, which is considered as the age of metamorphism, with a
456
similar weighted mean 207Pb/206Pb age of 1846±6 Ma (Fig. 8a). The rest spot analyses
457
performed on the detrital zircons are distributed on or close to the concordia, and the
458
207
459
of the detrital zircons.
Pb/206Pb ages range from 2001 Ma to 2255 Ma, interpreted to be the formation age
21
460
In sample S18, zircon grains are also stubby columnar and round in shape and
461
about 100–200 µm in length. Some zircons show homogeneous texture with low
462
luminescence in cathodoluminescence (CL) images (Fig. 7b) implying possible origin
463
of metamorphism. Some zircons show core-rim structures in CL images (Fig. 7b). The
464
cores display oscillatory zonings, indicative of magmatic origin. Around the cores are
465
homogeneous rims with higher luminescence, indicative of possible metamorphic
466
origin. Twenty-three spot analyses were conducted on twenty zircon grains. The U,
467
Th contents and the Th/U ratios of the fourteen valid analytical spots on the zircon
468
rims or metamorphic grains are in the range of 13–124 ppm, 5–19 ppm and 0.08–0.36,
469
respectively. All of these analytical spots define a linear array on the concordia
470
diagram and yield an upper intercept age of 1818±22 Ma, possibly reflecting the age
471
of the metamorphic event, with a similar weighted mean
472
Ma (Fig. 8b). The rest eight valid spots analyzed on the magmatic cores also define a
473
linear array on the concordia diagram, yielding an upper intercept age of 2547±47 Ma,
474
possibly reflecting an age of one magmatic event; and a lower intercept age of
475
1792±310 Ma, which is close to the age of metamorphism (Fig. 8b).
476
7. Discussion
207
Pb/206Pb age of 1823±8
477
The North China Craton (NCC) is one of the oldest and largest cratons in the
478
world (as old as ~3.8 Ga; Liu et al., 1992) with widespread Archean to
479
Paleoproterozoic basement, albeit whose Precambrian crustal history is hotly debated.
480
A number of tectonic subdivision models have been proposed for the formation and
481
evolution of the basement of the NCC (eg., Wu et al., 1998; Zhao et al., 1998, 2000a,
22
482
2001a, 2005, 2012; Zhai et al., 2000, 2005, 2010; Kusky and Li, 2003; Santosh et al.,
483
2006; Faure et al., 2007; Trap et al., 2007, 2012; Zhai and Peng, 2007; Santosh, 2010;
484
Kusky, 2011; Zhai and Santosh, 2011; Peng et al., 2014). A broad consensus among
485
these diverse models is that there is a S–N-trending Paleoproterozoic tectonic belt in
486
the central part of the NCC, named either the Trans-North China Orogen (TNCO;
487
Zhao et al., 2001a, 2005), or the Central Orogenic Belt (Kusky and Li, 2003; Santosh,
488
2010; Kusky, 2011) or the Jinyu Orogenic Belt (Zhai and Peng, 2007) or the Fuping
489
Block (Faure et al., 2007; Trap et al., 2007, 2012), although there still remains
490
controversial about the boundaries of these belts. Another familiar debate focuses on
491
the formation timing of these belts, which were involved in the final amalgamation of
492
the NCC. For example, some researches believe that the final amalgamation of the
493
NCC occurred at ~1.85 Ga by continent-continent collision along the TNCO between
494
the Eastern and Western Blocks (e.g., Zhao et al., 1998, 2000a, 2012; Guo et al., 2005;
495
Kröner et al., 2005), whereas others argue that the collision between the Eastern and
496
Western Blocks occurred at ~2.5 Ga along the Central Orogenic Belt (Kusky and Li,
497
2003; Kusky, 2011). Moreover, some other different models are also presented (e.g.,
498
Faure et al., 2007; Trap et al., 2007, 2012; Zhai and Peng, 2007; Santosh, 2010; Zhai
499
et al., 2010). In the last two decades, from the north to the south, numerous
500
investigations have revealed that the metamorphic complexes in the TNCO all record
501
clockwise P–T paths with retrograde isothermal decompression (ITD) process, such as
502
the Huai’an complex (Zhai et al., 1993; Liu, 1997; Guo et al., 1998, 2002, 2005; Zhao
503
et al., 2008), the Hengshan complex (Wang et al., 1991; Guo et al., 1999; Zhao et al.,
23
504
2001b; Qian et al., 2015, 2016), the Wutai complex (Wang et al., 1996; Zhao et al.,
505
1999; Yu et al., 2001; Qian et al., 2013, 2016), the Fuping complex (Liu, 1996; Zhao
506
et al., 2000b), the Lüliang complex (Trap et al., 2009b; Zhao et al., 2010b), the
507
Zanhuang complex (Xiao et al., 2011), the Zuoquan complex (Xiao et al., 2014) and
508
the Taihua complex (Jiang et al., 2011; Lu et al., 2013, 2014; Wang et al., 2014; Chen
509
et al., 2015), which make it much more clear that the whole TNCO was involved in
510
the subduction- and collision- related processes during the amalgamation of the
511
Eastern and Western Blocks in the Paleoproterozoic, as suggested by Zhao et al.
512
(2001, 2005, 2012).
513
In this paper, it is found that the pelitic granulite from the Huashan complex
514
underwent similar tectonothermal processes. Clockwise P–T paths were reconstructed
515
for these pelitic granulite samples, also imply initial crustal thickening followed by
516
possible rapid exhumation. This is consistent with a subduction and then
517
continent-continent collision environment (England and Thompson, 1984; Bohlen,
518
1991; Lu, 1991). Fortunately, garnet-bearing amphibolites widely distribute in the
519
Taihua metamorphic complex, which record clockwise P–T paths with ITD segments,
520
indicating an initial crustal thickening followed by rapid exhumation/uplift.
521
Metamorphic evolution of the intercalated metapelitic granulites and amphibolites of
522
the Taihua complex, all suggest that the southern segment of the TNCO was also
523
involved in the amalgamation of the Eastern and Western Blocks in the
524
Paleoproterozoic.
24
525
It is widely accepted that the final amalgamation of the Eastern and Western
526
Blocks occurred at ~1.85 Ga (Zhao et al., 1998, 2000a, 2005), which was
527
demonstrated by the metamorphic ages obtained from the northern and middle
528
segments of the TNCO (e.g., Mao et al., 1999; Guo and Zhai, 2001; Zhao et al., 2002,
529
2008a,b, 2010a,b; Liu et al., 2004, 2007; Guo et al., 2005; Kröner et al., 2005, 2006;
530
Faure et al., 2007; Trap et al., 2007, 2008, 2012; Xiao et al., 2011, 2013). In recent
531
years, more and more older metamorphic ages were found from the metamorphic
532
complexes in the whole TNCO, such as 1.97–1.92 Ga from the Taihua complex (Jiang
533
et al., 2011; Wang et al., 2012, 2013, 2014; Lu et al., 2013, 2014, 2015; Diwu et al.,
534
2014; Chen et al., 2015), 1.95–1.91 Ga from the Lüliang complex (Liu et al., 2006;
535
Trap et al., 2009b), ~1.95 Ga from the Wutai complex (Qian et al., 2013), 1.96 Ga and
536
1.92 Ga from the Hengshan complex (Qian et al., 2015, 2016) and 1.95 Ga from the
537
Chengde complex (Qu et al., 2012). The widespread metamorphic ages of 1.97–1.80
538
Ga in the whole TNCO possibly indicate that the tectonothermal evolution of the
539
TNCO might be a long and complex process, which possibly started as early as ~1.97
540
Ga and lasted as late as 1.80 Ga (Chen et al., 2015).
541
Another controversy is about the polarity of the Neoarchean to Paleoproterozoic
542
subduction operated in the Tran-North China Orogen (Zhao and Zhai, 2013), mainly
543
including the eastward subduction model (Zhao et al., 2001a, 2005; Zhang et al., 2007,
544
2009, 2012) and the westward subduction model (e.g., Faure, et al., 2007; Trap et al.,
545
2007; Zhu and Zheng, 2009; Santosh, 2010; Wang et al., 2010; Kusky, 2011). The
546
metamorphic ages obtained from the Taihua complex was summarized in Table 7. We
25
547
can clearly conclude that the metamorphic ages of the Huashan complex in the west
548
(mostly≤1.90 Ga) are obviously younger than those of the Luoning, Lushan and
549
Wugang terranes in the east (mostly ≥1.90 Ga). This phenomenon possibly implies
550
that the tectonothermal event in the southern segment of the TNCO possibly started
551
from the east, and then extended to the west, which could be well explained by the
552
eastward-directed subduction model for the TNCO (Zhao et al., 2001a, 2005; Zhang
553
et al., 2007, 2009, 2012). Furthermore, the metamorphic P–T conditions of the
554
metamorphic peak show a gradually increasing trend in the pressure from the
555
Huashan terrane in the west (6.7–8.6 kbar/700–820 °C, Wang et al., 2014; this study)
556
to the Luoning, Lushan and Wugang terranes in the east (8.9–10.8 kbar/710–820 °C,
557
Lu et al., 2013, 2014; Chen et al., 2015). The existing of thermal relaxation in regions
558
where the crust is rapidly thickened (e.g., Richardson and England, 1979; England
559
and Thompson, 1984) tells us that the mineral reactions in metamorphic rocks are
560
more sensitive to the changes in pressure than in temperature. The obvious higher
561
pressure recorded in the east regions possibly implies a deeper subduction or more
562
degrees of crustal thickening occurred in the east, which also supports the
563
eastward-directed subduction model for the TNCO (Zhao et al., 2001a, 2005; Zhang
564
et al., 2007, 2009, 2012).
565
8. Conclusions
566
(1) Three generations of mineral assemblages have been identified in the pelitic
567
granulites from the Huashan terrane, Taihua metamorphic complex, southern
568
Trans-North China Orogen. Clockwise P–T paths were reconstructed by both
26
569
conventional thermobarometry and pseudosection modeling, which pass from 4–5
570
kbar/520–530 °C through 6.8–8.6 kbar/730–810 °C to 4.1–6.4 kbar/570–740 °C, and
571
suggest that the Huashan terrane was involved in the subduction/collision process
572
between the Eastern and Western Blocks along the Trans-North China Orogen.
573
(2) SIMS U–Pb dating of metamorphic zircons yielded metamorphic ages of
574
1823–1846 Ma. Combined with geochronological data from the literature, it is
575
concluded that the tectonothermal evolution of the Trans-North China Orogen could
576
be a long and complex process, which started as early as ~1.97 Ga and lasted as late
577
as 1.80 Ga.
578
(3) The older metamorphic ages and higher metamorphic peak pressures
579
preserved in the east region than those in the west of the Taihua complex suggest the
580
possible eastward-directed subduction model of the TNCO.
581 582
Acknowledgements
583
Professor Yong-Hong Shi and Miss Juan Wang are specially thanked for helping
584
the authors in electronic microprobe analyses. Xin Zhou and Xiao-Qiang Yang are
585
also thanked for their discussions and suggestions. The quality of the original
586
manuscript has been improved through reviews by two anonymous referees. This
587
work was supported by the National Natural Science Foundation of China (41225007,
588
40872125, 41130314).
589 590
References 27
591 592 593 594 595 596
Bohlen, S.R., 1987. Pressure–temperature–time paths and a tectonic model for the evolution of granulites. Journal of Geology 95, 617–632. Bohlen, S.R., 1991. On the formation of granulites. Journal of Metamorphic Geology 9, 223–229. Brown, M., 1993. P–T–t evolution of orogenic belts and the causes of regional metamorphism. Journal of the Geological Society 150, 227–241.
597
Brown, M., 2009. Metamorphic patterns in orogenic systems and the geological
598
record. Journal of the Geological Society, London, Special Publications 318,
599
37–74.
600
Chen, H.X., Wang, J., Wang, H., Wang, G.D., Peng, T., Shi, Y.H., Zhang, Q., Wu,
601
C.M., 2015. Metamorphism and geochronology of the Luoning metamorphic
602
terrane, southern terminal of the Palaeoproterozoic Trans-North China Orogen,
603
North China Craton. Precambrian Research 264, 156–178.
604
Chen HX, Wang HYC, Peng T and Wu CM (2016) Petrogenesis and geochronology
605
of the Neoarchean-Paleoproterozoic granitoid and monzonitic gneisses in the
606
Taihua complex: Episodic magmatism of the southwestern Trans-North China
607
Orogen. Precambrian Research, 287: 31–47.
608
Chen, L.G., Wang, B.Y., Xue, Y.Z., 1997. The re-establishment of Taihua Group in
609
Xiao Qinling, Shanxi. Geology of Shanxi 15, 20–30 (in Chinese with English
610
abstract).
611
Connolly, J.A.D., 2005. Computation of phase equilibria by linear programming: a
612
tool for geodynamic modeling and its application to subduction zone
28
613
decarbonation. Earth and Planetary Science Letters 236, 524–541.
614
Diwu, C.R., Sun, Y., Lin, C.L., Wang, H.L., 2010. LA–(MC)–ICPMS U–Pb zircon
615
geochronology and Lu–Hf isotope compositions of the Taihua Complex on the
616
southern margin of the North China Craton. Chinese Science Bulletin 55,
617
2557–2571.
618
Diwu, C.R., Sun, Y., Zhao, Y., Lai, S.C., 2014. Early Paleoproterozoic (2.45–2.20 Ga)
619
magmatic activity during the period of global magmatic shutdown: Implications
620
for the crustal evolution of the southern North China Craton. Precambrian
621
Research 255, 627–640.
622 623
Dooley, D.F., Patiño, Douce, A.E., 1996. Fluid-absent melting of F-rich phlogopite + rutile + quartz. American Mineralogist, 1996, 81, 202–212.
624
Droop, G.T.R., 1987. A general equation for estimating Fe3+ concentrations in
625
ferromagnesian silicates and oxides from microprobe analyses, using
626
stoichiometric criteria. Mineralogical Magazine 51, 431–435.
627
England, P.C., Richardson, S.W., 1977. The influence of erosion upon the mineral
628
facies of rocks from different metamorphic environments. Journal of the
629
Geological Society 134, 201–213.
630
England, P.C., Thompson, A.B., 1984. Pressure–temperature–time paths of regional
631
metamorphism I. Heat transfer during the evolution of regions of thickened
632
continental crust. Journal of Petrology 25, 894–928.
633
Faure, M., Trap, P., Lin, W., Monié, P., Bruguier, O., 2007. Polyorogenic evolution of
634
the Paleoproterozoic Trans-North China Belt, new insights from the
29
635
Lüliangshan–Hengshan–Wutaishan and Fuping massifs. Episodes 30, 1–12.
636
Guo, J.H., O’Brien, P.J., Zhai, M.G., 2002. High-pressure granulites in the Sanggan
637
area, North China Craton: Metamorphic evolution, P–T paths and geotectonic
638
significance. Journal of Metamorphic Geology 20, 741–756.
639
Guo, J.H., Sun, M., Chen, F.K., Zhai, M.G., 2005. Sm–Nd and SHRIMP U–Pb zircon
640
geochronology of high-pressure granulites in the Sanggan area, North China
641
Craton: Timing of Paleoproterozoic continental collision. Journal of Asian Earth
642
Sciences 24, 629–642.
643
Guo, J.H., Zhai, M.G., 2001. Sm–Nd age dating of high-pressure granulites and
644
amphibolite from Sanggan area, North China craton. Chinese Science Bulletin
645
46, 106–111.
646
Guo, J.H., Zhai, M.G., Li, Y.G., Li, J.H., 1999. Metamorphism, P–T paths and
647
tectonic significance of garnet amphibolite and granulite from Hengshan, North
648
China Craton. Scientia Geologica Sinica 34, 311–325 (in Chinese with English
649
abstract).
650
Guo, J.H., Zhai, M.G., Li, Y.G., Yan, Y.H., 1998. Contrasting metamorphic P–T
651
paths of Archaean high pressure granulites from the North China Craton:
652
metamorphism and tectonic significance. Acta Petrologica Sinica 14, 430–448
653
(in Chinese with English abstract).
654 655 656
Harley, S.L., 1989. The origins of granulites, a metamorphic perspective. Geological Magazine 126, 215–247. Holdaway, M.J., 2000. Application of new experimental and garnet Margules data to
30
657
the garnet–biotite geothermometer. American Mineralogist 85, 881–892.
658
Holdaway, M.J., Mukhopadhyay, B., 1993. A re-evaluation of the stability relations of
659
andalusite: thermochemical data and phase diagram for the aluminum silicates.
660
American Mineralogist 78, 298–315.
661 662
Holland, T.J.B., Powell, R., 1998. An internally consistent thermodynamic data set for phases of petrological interest. Journal of Metamorphic Geology 16, 309–343.
663
Huang, X.L., Niu, Y.L., Xu, Y.G., Yang, Q.J., Zhong, J.W., 2010. Geochemistry of
664
TTG and TTG-like gneisses from Lushan–Taihua complex in the southern North
665
China Craton: Implications for late Archean crustal accretion. Precambrian
666
Research 182, 43–56.
667
Huang, X.L., Wilde, S.A, Yang, Q.J., Zhong, J.W., 2012. Geochronology and
668
petrogenesis of gray gneisses from the Taihua Complex at Xiong'er in the
669
southern segment of the Trans-North China Orogen: Implications for tectonic
670
transformation in the Early Paleoproterozoic. Lithos 134–135, 236–252.
671
Huang, X.L., Wilde, S.A, Zhong, J.W., 2013. Episodic crustal growth in the southern
672
segment of the Trans-North China Orogen across the Archean–Proterozoic
673
boundary. Precambrian Research 233, 337–357.
674
Jiang, Z.S., Wang, G.D., Xiao, L.L., Diwu, C.R., Lu, J.S., Wu, C.M., 2011.
675
Paleoproterozoic metamorphic P–T–t path and tectonic significance of the
676
Luoning metamorphic complex at the southern terminal of the Trans-North
677
China Orogen,Henan Province. Acta Petrologica Sinica 27, 3701–3717 (in
678
Chinese with English abstract).
31
679
Kang, C.H., Li, M.X., 1988. Rehabilitation of the characteristics of the metamorphic
680
original rocks under the Taihua Group in Tongguan region, Shanxi province,
681
Journal of Xi’an College of Geology 10, 1–13 (in Chinese with English
682
abstract).
683 684
Kohn, M.J., Spear, F., 2000. Retrograde net transfer reaction insurance for pressure–temperature estimates. Geology 28, 1127–1130.
685
Kröner, A., Wilde, S.A., Li, J.H., Wang, K.Y., 2005. Age and evolution of a late
686
Archean to early Palaeoproterozoic upper to lower crustal section in the
687
Wutaishan/Hengshan/Fuping terrain of northern China. Journal of Asian Earth
688
Science 24, 577–595.
689
Kröner, A., Wilde, S.A., Zhao, G.C., O’Brien, P.J., Sun, M., Liu, D.Y., Wan, Y.S.,
690
Liu, S.W., Guo, J.H., 2006. Zircon geochronology of mafic dykes in the
691
Hengshan Complex of northern China: evidence for late Palaeoproterozoic
692
rifting and subsequent high pressure event in the North China Craton.
693
Precambrian Research 146, 45–67.
694 695 696 697 698
Kusky, T.M., 2011. Geophysical and geological tests of tectonic models of the North China Craton. Gondwana Research 20, 26–35. Kusky, T.M., Li, J.H., 2003. Paleoproterozoic tectonic evolution of the North China craton. Journal of Asian Earth Sciences 22, 23–40. Lal, R.K., 1993. Internally consistent recalibrations of mineral equilibria for
699
geothermobarometry
involving
garnet–orthopyroxene–plagioclase–quartz
700
assemblages and their application to the South Indian granulites. Journal of
32
701
Metamorphic Geology 11, 855–866.
702
Li, X.H., Liu, Y., Li, Q.L., Guo, C.H., Chamberlain, K.R., 2009. Precise
703
determination of Phanerozoic zircon Pb/Pb age by multicollector SIMS without
704
external standardization. Geochemistry Geophysics Geosystem 10, Q04010.
705
doi:10.1029/cGC002400.
706
Liu, D.Y., Nutman, A.P., Compston, W., Wu, J.S., Shen, Q.H., 1992. Remnants of
707
≥3800 Ma crust in the Chinese part of the Sino-Korean Craton. Geology 20,
708
339–342.
709
Liu, D.Y., Wilde, S.A., Wan, Y.S., Wang, S.Y., Valley, J.W., Kita, N., Dong, C.Y.,
710
Xie, H.Q., Yang, C.X., Zhang, Y.X., Gao, L.Z., 2009. Combined U–Pb, hafnium
711
and oxygen isotope analysis of zircons from meta-igneous rocks in the southern
712
North China Craton reveal multiple events in the Late Mesoarchean–Early
713
Neoarchean. Chemical Geology 261, 140–154.
714
Liu, F.L., 1997. The Metamorphic Reaction and Water Activity of Basic Granulite in
715
the Datong–Huaian Region. Acta Petrologica Sinica 13, 27–43 (in Chinese with
716
English abstract).
717 718
Liu, S.W., 1996. Study on the P–T path of granulites in Fuping area, Hebei Province. Geological Journal of Universities 2, 75–84 (in Chinese with English abstract).
719
Liu, S.W., Shu, G.M., Pan, Y.M., Dang, Q.N., 2004. Electron-microprobe dating of
720
monazite and metamorphic age of Wutai Group, Wutai Mountains. Geological
721
Journal of China Universities 10, 356–363 (in Chinese with English abstract).
722
Liu, S.W., Zhang, C., Liu, C.H., L, Q.G., Lü, Y.J., Yu, S.Q., Tian, W., Feng, Y.G.,
33
723
2007. EPMA Th–U–Pb dating of monazite for Zhongtiao and Lüliang
724
Precambrian metamorphic complexes. Earth Science Frontiers 14, 64–74 (in
725
Chinese with English abstract).
726
Liu, S.W., Zhao, G.C., Wilde, S.A., Shu, G.M., Sun, M., Li, Q.G., Tian, W. Zhang, J.,
727
2006. Th–U–Pb monazite geochronology of the Lüliang and Wutai Complexes:
728
Constraints on the tectonothermal evolution of the Trans-North China Orogen.
729
Precambrian Research 148, 205–224.
730
Lu, J.S., Wang, G.D., Wang, H., Chen, H.X., Peng, T., Wu, C.M., 2015. Zircon SIMS
731
U–Pb geochronology of the Lushan terrane: dating metamorphism of the
732
southwestern terminal of the Palaeoproterozoic Trans-North China Orogen.
733
Geological Magazine152, 367–377.
734
Lu, J.S., Wang, G.D., Wang, H., Chen, H.X., Wu, C.M., 2013. Metamorphic P–T–t
735
paths retrieved from the amphibolites, Lushan terrane, Henan Province and
736
reappraisal of the Paleoproterozoic tectonic evolution of the Trans-North China
737
Orogen. Precambrian Research 238, 61−67.
738
Lu, J.S., Wang, G.D., Wang, H., Chen, H.X., Wu, C.M., 2014. Palaeoproterozoic
739
metamorphic evolution and geochronology of the Wugang block, southeastern
740
terminal of the Trans-North China Orogen. Precambrian Research 251,
741
197−211.
742 743 744
Lu, L.Z., 1991. Metamorphic P–T–t paths and their geodynamic implications. Overseas Precambrian Geology 3, 4–20 (in Chinese). Ludwig, K.R., 2003. Isoplot 3.0-A geochronological toolkit for Micro-soft Excel.
34
745
Berkeley Geochronology Center, Special Publication 4, 1–70.
746
Ma, J., Wang, R.M., 1994. Reviews in garnet–clinopyroxene geothermometers and
747
geobarometers with their application to granulite: the comparison of Miyun
748
(Zunhua) and Xuanhua granulite forming conditions. In: Qian, X.L., Wang, R.M.
749
(eds.) Geological evolution of the granulite Terrane in North Part of the North
750
China Craton. Seismological Press, Beijing, pp. 71–88 (in Chinese with English
751
abstract).
752
Mao, D.B., Zhong, C.T., Chen, Z.H., Lin, Y.X., Li, H.M., Hu, X.D., 1999. Isotopic
753
ages and geological implications of high-pressure mafic granulites in the
754
northern Chengde area, Hebei Province, China. Acta Petrologica Sinica 15,
755
524–534.
756
Mei, H.L., 1994. Metamorphic P–T–t paths and tectonic evolution of early
757
Proterozoic rocks from the Zhongtiao Mountains, southern Shanxi. Geological
758
Review 40, 36–45 (in Chinese with English abstract).
759 760
Miyashiro, A., 1961. Evolution of metamorphic belts. Journal of Petrology 2, 277–311.
761
Newton, R.C., Charlum, T.V., Kleppa, O.J., 1980. Thermochemistry of the high
762
structural state plagioclases. Geochemica Cosmochimica Acta 44, 933–941.
763
Nicollet, C., Goncalves, P., 2005. Two contrasted P–T–time paths of coronitic
764
metanorites of the French Massif Central: are reaction textures reliable guides to
765
metamorphic histories? Journal of Metamorphic Geology 23, 97–105.
766
O’Brien, P.J., Walte, N., Li, J.H., 2005. The petrology of two distinct granulite types
35
767
in the Hengshan Mts, China, and tectonic implications. Journal of Asian Earth
768
Sciences 24, 615–627.
769
Pattison, D.R.M., 1992. Stability of andalusite and sillimanite and the Al2SiO5 triple
770
point: constraints from the Ballachulish aureole, Scotland. Journal of Geology
771
100, 423–446.
772
Peng, P., Wang, X.P., Windley, B.F., Guo, J.H., Zhai, M.G., Li, Y., 2014. Spatial
773
distribution of ~1950–1800 Ma metamorphic events in the North China Craton:
774
Implications for tectonic subdivision of the craton. Lithos 202–203, 250–266.
775
Peterson, J.W., Chacko, T., Kuehner, S.M., 1991. The effects of fluorine on the
776
vapor-absent melting of phlogopite + quartz: implications for deep crustal
777
processes. American Mineralogist 76, 470–476.
778 779
Powell, P., Holland, T.J.B., 2008. On thermobarometry. Journal of Metamorphic Geology 26, 155–179.
780
Qi, J.Y., 1991. Amphiboles from basic metamorphic rocks in the Archeozoic Taihua
781
Group and its genetic significance. Journal of Hebei College of Geology 14,
782
144–157 (in Chinese with English abstract).
783
Qi, J.Y., 1992. Metamorphic rock series of Taihua Group and conditions for its
784
formation in eastern Qinling. Scientia Geologica Sinica 8(Supplementary),
785
95–107 (in Chinese with English abstract).
786
Qian, J.H., Wei, C.J., 2016. P–T–t evolution of garnet amphibolites in the
787
Wutai-Hengshan area, North China Craton: insights from phase equilibria and
788
geochronology. Journal of Metamorphic Geology 34, 423–446.
36
789
Qian, J.H., Wei, C.J., Clarke, G.L., Zhou, X.W., 2015. Metamorphic evolution and
790
zircon ages of garnet–orthoamphibole rocks in southern Hengshan, North China
791
Craton: insight into the regional Paleoproterozoic P–T–t history. Precambrian
792
Research 256, 223–240.
793
Qian, J.H., Wei, C.J., Zhou, X.W., Zhang, Y.H., 2013. Metamorphic P–T paths and
794
new zircon U–Pb age data for garnet–mica schist from the Wutai Group, North
795
China Craton. Precambrian Research 233, 282–296.
796
Qu, J.F., Li, J.Y., Liu, J.F., 2012. Geochronological study on the Fenghuangzui
797
complex of Dantazi Group at northern Hebei Province. Acta Petrologica Sinica
798
28, 2879–2889 (in Chinese with English abstract).
799
Richardson, S.W., England, P.C., 1979. Metamorphic consequences of crustal eclogite
800
production in over thrust orogenic zone. Earth and Planetary Science Letters 42,
801
183–190.
802
Sandiford, M., Powell, R., 1986. Deep crustal metamorphism during continental
803
extension: modern and ancient examples. Earth and Planetary Science Letters 79
804
(1–2), 151–158.
805
Santosh, M., 2010. Assembling North China Craton within the Columbia
806
supercontinent: the role of double-sided subduction. Precambrian Research 178,
807
149–167.
808
Santosh, M., Sajeev, K., Li, J.H., 2006. Extreme crustal metamorphism during
809
Columbia supercontinent assembly: evidence from North China Craton.
810
Gondwana Research 10, 256–266.
37
811
Sláma, J., Košler, J., Condon, D.J., Crowley, J.L., Gerdes, A., Hanchar, J.M.,
812
Horstwood, M.S.A., Morris, G.A., Nasdala, L., Norberg, N., Schaltegger, U.,
813
Schoene, B., Tubrett, M.N., Whitehouse, M.J., 2008. Plešovice zircon—A new
814
natural reference material for U–Pb and Hf isotopic microanalysis. Chemical
815
Geology 249, 1–35.
816 817 818 819
Spear, F.S., 1992. Thermobarometry and P–T paths from granulite facies rocks: an introduction. Precambrian Research 55, 201–207. Spear, F.S., 1993. Metamorphic phase equilibria and pressure–temperature–time paths. Mineralogical Society of America, Washington, D. C., pp. 15–22.
820
Spear, F.S., Hickmott, D.D., Selverstone, J., 1990. Metamorphic consequences of
821
thrust emplacement, Fall Mountain, New Hampshire. Geological Society of
822
America Bulletin 102, 1344–1360.
823 824 825 826
Spear, F.S., Florence, F., 1992. Thermobarometry in granulites: pitfalls and new approaches. Precambrian Research 55, 209–241. Stacey, J.S., Kramers, J.D., 1975. Approximation of terrestrial lead isotope evolution by a two-stage model. Earth and Planetary Science Letters 26, 207–221.
827
Tajcmanová, L., Connolly, J.A.D., Cesare, B., 2009. A thermodynamic model for
828
titanium and ferric iron solution in biotite. Journal of Metamorphic Geology 27,
829
153–64.
830
Trap, P., Faure, M., Lin, W., Breton, N.L., Monié, P., 2012. The Paleoproterozoic
831
evolution of the Trans-North China Orogen: Toward a comprehensive model.
832
Precambrian Research 222–223, 191–211.
38
833
Trap, P., Faure, M., Lin, W., Meffre, S., 2009b. The Lüliang Massif: a key area for the
834
understanding of the Palaeoproterozoic Trans-North China Belt, North China
835
Craton. Journal of the Geological Society, London, Special Publication 33,
836
99–125.
837
Trap, P., Faure, M., Lin, W., Monié, P., 2007. Late Palaeoproterozoic (1900–1800 Ma)
838
nappe stacking and polyphase deformation in the Hengshan–Wutaishan area:
839
Implications for the understanding of the Trans-North China Belt, North China
840
Craton. Precambrian Research 156, 85–106.
841
Trap, P., Faure, M., Lin, W., Monié, P., Bruguier, O., 2008. Contrasted tectonic styles
842
for the Paleoproterozoic evolution of the North China Craton: evidence for a 2.1
843
Ga thermal and tectonic event in the Fuping Massif. Journal of Structure
844
Geology 30, 1109–1125.
845
Trap, P., Faure, M., Lin, W., Monié, P., Meffre, S., Melletton, J., 2009a. The
846
Zanhuang Massif, the second and eastern suture zone of the Paleoproterozoic
847
Trans-North China Orogen. Precambrian Research 172, 80–98.
848
Vernon, R.H., White, R.W., Clarke, G.L., 2008. False metamorphic events inferred
849
from misinterpretation of microstructural evidence and P–T data. Journal of
850
Metamorphic Geology 26, 437–449.
851
Waldbaum, D.R., Thompson, J.B., 1968. Mixing Properties of Sanidine Crystalline
852
Solutions. 2. Calculations Based On Volume Data. American Mineralogist 53,
853
2000.
854
Wan, Y.S., Wilde, S.A., Liu, D.Y., Yang, C.X., Song, B., Yin, X.Y., 2006. Further
39
855
evidence for ~1.85 Ga metamorphism in the Central Zone of the North China
856
Craton: SHRIMP U–Pb dating of zircon from metamorphic rocks in the Lushan
857
area, He’nan Province. Gondwana Research 9, 189–197.
858
Wang, G.D., Lu, J.S., Wang, H., Chen, H.X., Xiao, L.L., Diwu, C.R., Ji, J.Q., Wu, 40
Ar/39Ar dating of
859
C.M., 2013. LA–ICP–MS U–Pb dating of zircons and
860
amphiboles of the Taihua Metamorphic Complex, Huashan, southern terminal of
861
the Paleoprotorozoic Trans-North China Orogen. Acta Petrologica Sinica 29,
862
3099–3114 (in Chinese with English abstract).
863
Wang, G.D., Wang, H., Chen, H.X., Lu, J.S., Xiao, L.L., Wu, C.M., 2012. U–Pb
864
dating of zircons from metamorphic rocks of the Taihua Metamorphic Complex,
865
Huashan, Southern Margin of the Trans-North China Orogen. Acta Geologica
866
Sinica 86, 1541–1551 (in Chinese with English abstract).
867
Wang, G.D., Wang, H., Chen, H.X., Lu, J.S., Wu, C.M., 2014. Metamorphic
868
evolution and zircon U–Pb geochronology of the Mts. Huashan amphibolites:
869
Insights into the Palaeoproterozoic amalgamation of the North China Craton.
870
Precambrian Research 245, 100−114.
871
Wang, G.D., Wang, H., Chen, H.X., Zhang, Bo., Zhang, Q., Wu, C.M., 2016.
872
Geochronology and geochemistry of the TTG and potassic granite of the Taihua
873
complex, Mts. Huashan: implications for crustal evolution of the southern North
874
China
875
http://dx.doi.org/10.1016/j.precamres.2016.11.006.
876
Craton.
Precambrian
Research,
Wang, K.Y., Zhou, S.P., Hao, J., 1996. The metamorphism and significance of
40
877
kyanitebearing assemblages from the original jingangku formation of Wutaishan
878
area. Acta Petrologica Sinica 12, 88–98 (in Chinese with English abstract).
879
Wang, R.M., Chen, Z.Z., Chen, F., 1991. Grey tonalitic gneiss and high-pressure
880
granulite inclusions in Hengshan, Shanxi Province, and their geological
881
significance. Acta Petrologica Sinica 7, 36–46 (in Chinese with English
882
abstract).
883
Wang, Z.H., Wilde, S.A., Wan, J.L., 2010. Tectonic setting and significance of
884
2.3–2.1 Ga magmatic events in the Trans-North China Orogen: new constraints
885
from
886
Hengshan–Wutai–Fuping area. Precambrian Research 178, 27–42.
the
Yanmenguan
mafic–ultramafic
intrusion
in
the
887
White, R.W., Powell, R., Holland, T.J.B., 2007. Progress relating to calculation of
888
partial melting equilibria for metapelites. Journal of Metamorphic Geology 25,
889
511–527.
890
White, R.W., Powell, R., Holland, T.J.B., Worley, B.A., 2000. The effect of TiO2 and
891
Fe2O3 on metapelitic assemblages at greenschist and amphibolite facies
892
conditions:
893
K2O–FeO–MgO–Al2O3–SiO2–H2O–TiO2–Fe2O3.
894
Geology 18, 497–511.
895 896 897 898
mineral
equilibria
calculations
in
Journal
the of
system
Metamorphic
Whitney, D.L., Evans, B.W., 2010. Abbreviations for names of rock-forming minerals. American Mineralogist 95, 185–187. Wu, C.M., Chen, H.X., 2015. Revised Ti-in-biotite geothermometer for ilmenite-or rutile-bearing crustal metapelites. Science Bulletin 60 (1), 116–121.
41
899
Wu, C.M., Cheng B.H., 2006. Valid garnet-biotite (GB) geothermometry and
900
garnet–aluminum
silicate–plagioclase–quartz
901
metapelitic rocks. Lithos 89, 1–23.
(GASP)
geobarometry
in
902
Wu, C.M., Lu, J.S., Wang, G.D., 2014. Determination of Pressure–Temperature
903
Conditions of Retrograde Symplectitic Assemblages in Granulites and
904
Amphibolites. Global Journal Earth Science and Engineering 1, 71–83.
905
Wu, C.M., Zhang J., Ren L.D., 2004. Empirical garnet–biotite–plagioclase–quartz
906
(GBPQ) geobarometry in medium to high-grade metapelitic gneisses. Journal of
907
Petrology 45, 1907–1921.
908
Wu, J.S., Geng, Y.S., Shen, Q.H., Wan, Y.S., Liu, D.Y., Song, B., 1998. Archean
909
Geological
Characteristics
and
Tectonic
Evolution
of
China-Korea
910
Paleo-Continent. Geological Publishing House, Beijing, pp. 192–211 (in
911
Chinese with English abstract).
912
Xiao, L.L., Liu, F.L., Chen, Y., 2014. Metamorphic P–T–t paths of the Zanhuang
913
metamorphic complex: implications for the Paleoproterozoic evolution of the
914
Trans-North China Orogen. Precambrian Research 255, 216–235.
915
Xiao, L.L., Wang, G.D., Wang, H., Jiang, Z.S., Diwu, C.R., Wu, C.M., 2013. Zircon
916
U–Pb geochronology of the Zanhuang metamorphic complex: reappraisal of the
917
Paleoproterozoic amalgamation of the Trans-North China Orogen. Geological
918
Magazine 150, 756–764.
919
Xiao, L.L., Wu, C.M., Zhao, G.C., Guo, J.H., Ren, L.D., 2011. Metamorphic P–T
920
paths of the Zanhuang amphibolitic gneisses and metapelitic gneisses:
42
921
Constraints on the tectonic evolution of the Paleoproterozoic Trans-North China
922
Orogen. International Journal of Earth Sciences 100, 717–739.
923
Yang, C.X., 2008. Zircon SHRIMP U–Pb ages, geochemical characteristics and
924
environmental evolution of the Early Precambrian metamorphic series in the
925
Lushan area, Henan, China. Geological Bulletin of China 27, 517–533 (in
926
Chinese with English abstract).
927
Yu, L.J., Wang, K.Y., Wang, Z.H., Li, J.L., Fang, A.M., 2001. Early Proterozoic
928
high-pressure metamorphism in the Wutaishan. Acta Petrologica Sinica 17,
929
301–313 (in Chinese with English abstract).
930
Yu, X.Q., Liu, J.L., Li, C.L., Chen, S.Q., Dai, Y.P., 2013. Zircon U–Pb dating and Hf
931
isotope analysis on the Taihua Complex: Constraints on the formation and
932
evolution of the Trans-North China Orogen. Precambrian Research 230, 31–34.
933
Zhai, M.G., Bian, A.G., Zhao, T.P., 2000. The amalgamation of the supercontinent of
934
North China craton at the end of the Neoarchaean and its breakup during late
935
Palaeoproterozoic and Mesoproterozoic. Science in China Series D: Earth
936
Sciences 43, 219–232.
937
Zhai, M.G., Guo, J.H., Liu, W.J., 2005. Neoarchean to Paleoproterozoic continental
938
evolution and tectonic history of the North China Craton: A review. Journal of
939
Asian Earth Sciences 24, 547–561.
940
Zhai, M.G., Guo, J.H., Yan, Y.H., Li, Y.G., Han, X.L., 1993. Discovery of
941
high-pressure basic granulite terrain in north China Archaean Craton and
942
preliminary study. Science in China Series B 36, 1402–1408.
43
943
Zhai, M.G., Li, T.S., Peng, P., Hu, B., Liu, F., Zhang, Y.B., Guo, J.H., 2010.
944
Precambrian key tectonic events and evolution of the North China Craton. In:
945
Kusky, T.M., Zhai, M.G., Xiao, W.J. (Eds.), The Evolving Continents. Journal
946
of the Geological Society, London, Special Publications 338, 235–262.
947 948 949 950
Zhai, M.G., Peng, P., 2007. Paleoproterozoic events in North China Craton. Acta Petrologica Sinica 23, 2665–2682 (in Chinese with English abstract). Zhai, M.G., Santosh, M., 2011. The early Precambrian odyssey of North China Craton. A synoptic overview. Gondwana Research 20, 6–25.
951
Zhang, J., Zhao, G.C., Li, S.Z., Sun, M., Chan, L.S., Shen, W.L., Liu, S.W., 2012.
952
Structural and aeromagnetic studies of the Wutai Complex: implications for the
953
tectonic evolution of the Trans-North China Orogen. Precambrian Research
954
222–223, 212–229.
955
Zhang, J., Zhao, G.C., Li, S.Z., Sun, M., Liu, S.W., Wilde, S.A., Kröner, A., Yin,
956
C.Q., 2007. Deformation history of the Hengshan Complex: implications for the
957
tectonic evolution of the Trans-North China Orogen. Journal of Structural
958
Geology 29, 933–949.
959
Zhang, J., Zhao, G.C., Li, S.Z., Sun, M., Wilde, S.A., Liu, S.W., Yin, C.Q., 2009.
960
Polyphase deformation of the Fuping Complex, Trans-North China Orogen:
961
structures, SHRIMP U–Pb zircon ages and tectonic implications. Journal of
962
Structural Geology 31, 177–193.
963
Zhao, G.C., Cawood, P.A., Li, S.Z., Wilde, S.A., Sun, M., Zhang, J., He, Y.H., Yin,
964
C.Q., 2012. Amalgamation of the North China Craton: Key issues and
44
965
discussion. Precambrian Research 222–223, 55–76.
966
Zhao, G.C., Cawood, P.A., Lu, L.Z., 1999. Petrology and P–T history of the Wutai
967
amphibolites: implications for tectonic evolution of the Wutai Complex, China.
968
Precambrian Research 93, 181–199.
969
Zhao, G.C., Cawood, P.A., Wilde, S.A., Lu, L.Z., 2001b. High-pressure granulites
970
(retrograded eclogites) from the Hengshan Complex, North China Craton:
971
petrology and tectonic implications. Journal of Petrology 42, 1141–1170.
972
Zhao, G.C., Cawood, P.A., Wilde, S.A., Sun, M., Lu, L.Z., 2000a. Metamorphism of
973
basement rocks in the Central Zone of the North China Craton: implications for
974
Paleoproterozoic tectonic evolution. Precambrian Research 103, 55–88.
975
Zhao, G.C., Kröner, A., Wilde, S.A., Sun, M., Li, S.Z., Li, X.P., Zhang, J., Xia, X.P.,
976
He, Y.H., 2007. Lithotectonic elements and geological events in the
977
Hengshan–Wutai–Fuping belt: a synthesis and implications for the evolution of
978
the Trans-North China Orogen. Geological Magazine 144, 753–775.
979
Zhao, G.C., Sun, M., Wilde, S.A., Li, S.Z., 2005. Neoarchaean to Palaeoproterozoic
980
evolution of the North China Craton: Key issues revisited. Precambrian
981
Research 136, 177–202.
982
Zhao, G.C., Wilde, S.A., Cawood, P.A., Lu, L.Z., 1998. Thermal evolution of the
983
Archaean basement rocks from the eastern part of the North China Craton and
984
its bearing on tectonic setting. International Geology Review 40, 706–721.
985
Zhao, G.C., Wilde, S.A., Cawood, P.A., Lu, L.Z., 2000b. Petrology and P–T path of
986
the Fuping mafic granulites: implications for tectonic evolution of the central
45
987
zone of the North China Craton. Journal of Metamorphic Geology 18, 375–391.
988
Zhao, G.C., Wilde, S.A., Cawood, P.A., Sun, M., 2001a. Archean blocks and their
989
boundaries in the North China Craton: lithological, geochemical, structural and
990
P–T path constraints and tectonic evolution. Precambrian Research 107, 45–3.
991
Zhao, G.C., Wilde, S.A., Cawood, P.A., Sun, M., 2002. SHRIMP U–Pb zircon ages of
992
the Fuping Complex: Implications for Late Archean to Paleoproterozoic
993
accretion and assembly of the North China Craton. American Journal of Science
994
302, 191–226.
995
Zhao, G.C., Wilde, S.A., Sun, M., Guo, J.H., Kröner, A., Li, S.Z., Li, X.P., Wu, C.M.,
996
2008a. SHRIMP U–Pb zircon geochronology of the Huaian Complex:
997
constraints on Late Archean to Paleoproterozoic crustal accretion and collision
998
of the Trans-North China Orogen. American Journal of Science 308, 270–303.
999
Zhao, G.C., Wilde, S.A., Sun, M., Li, S.Z., Li, X.P., Zhang, J., 2008b. SHRIMP U–Pb
1000
zircon ages of granitoid rocks in the Lüliang Complex: Implications for the
1001
accretion and evolution of the Trans-North China Orogen. Precambrian
1002
Research 160, 213–226.
1003
Zhao, G.C., Li, S.Z., Zhang, J., Xia, X.P., 2010a. A comment on tectonic evolution of
1004
the Hengshan–Wutai–Fuping complexes and its implication for the Trans-North
1005
China Orogen. Precambrian Research 176, 94–98.
1006
Zhao, G.C., Yin, C.Q., Guo, J.H., Sun, M., Li, S.Z., Li, X.P., Wu, C.M., Liu, C.H.,
1007
2010b. Metamorphism of the Lüliang amphibolite: implications for the tectonic
1008
evolution of the North China Craton. American Journal of Science 310,
46
1009
1480–1502.
1010
Zhao, G.C., Zhai, M.G., 2013. Lithotectonic elements of Precambrian basement in the
1011
North China Craton: Review and tectonic implications. Gondwana Research 23,
1012
1207–1240.
1013
Zhou, H.W., Li, X.H., Zhong, Z.Q., Liu, Y., Xu, Q.D., 1997. Geochemistry of
1014
amphibolites within the Taihua complex from the Xiao Qinling area, western
1015
Henan and its tectonic implication. Geochimica 26, 87–100 (in Chinese with
1016
English abstract).
1017
Zhou, H.W., Zhong, Z.Q., Ling, W.L., Zhong, G.L., Xu, Q.D., 1998. Sm–Nd isochron
1018
for the amphibolites within Taihua complex from the Xiao Qinling area, western
1019
Henan and its geological implications. Geochimica 27, 367–372 (in Chinese
1020
with English abstract).
1021
Zhu, R.X., Zheng, T.Y., 2009. Destruction geodynamics of the North China craton
1022
and its Paleoproterozoic plate tectonics. Chinese Science Bulletin 19,
1023
3354–3366.
1024
Figure captions
1025 1026
Fig. 1. (a) Geological sketch map of the North China Craton showing the Mts.
1027
Huashan metamorphic terrane in the Trans-North China Orogen (from Zhao et al.
1028
1998, 2005) and (b) Geological sketch map of the Mts. Huashan metamorphic terrane,
1029
modified after the 1:200000 Weinan and Luonan Geological Maps. Sample locations
1030
are depicted.
47
1031
Fig. 2. Photomicropetrographs of the Mts. Huashan pelitic granulite samples (a)
1032
S18, (b–c) S25 and (d) S37, respectively. Dotted lines with arrowheads represent the
1033
EMP analytical profiles of the garnets. Mineral inclusions of Bt1 + Pl1 + Qz1 ± Ilm1
1034
within the garnet porphyroblasts comprise the prograde (M1) mineral assemblages.
1035
The metamorphic peak mineral assemblages (M2) are consisted of garnet
1036
porphyroblasts (Grt2) and matrix minerals Opx2 + Bt2+ Pl2 + Qz2 ± Ilm2 ± Mag2 ±
1037
zircon. The retrograde symplectic assemblages (M3) are consisted of Bt3 + Pl3 + Qz3 ±
1038
Opx3.
1039 1040 1041 1042
Fig. 3. X-ray compositional mapping of Fe, Mg, Ca and Mn of garnet porphyroblasts of the pelitic granulite samples (a) S18, (b) S25 and (c) S37. Fig. 4. Analytical chemical profiles of garnet porphyroblasts in the Mts. Huashan pelitic granulite samples (a) S18, (b) S25 and (c) S37.
1043
Fig. 5. Metamorphic P–T paths retrieved from the Mts. Huashan pelitic granulite
1044
samples (a) S18, (b) S25 and (c) S37. The Al2SiO5 phase transition lines are after
1045
Holdaway and Mukhopadhyay (1993), and the dashed lines are after Pattison (1992).
1046
The metamorphic facies and metamorphic facies series are from Spear (1993, p.
1047
15–22).
1048
Fig. 6. The P–T pseudosection calculated for the Huashan pelitic granulite
1049
(sample S18) in the NCKFMASHT system. The isopleths of Xgrs, XAlm and XPyr of
1050
garnet are also shown.
1051 1052
Fig. 7. The representative cathodoluminescence (CL) images of zircons separated from (a) pelitic granulite sample S7 and (b) pelitic granulite sample S18.
48
1053 1054
Fig. 8. The U–Pb concordia diagrams of analytical zircons of (a) pelitic granulite sample S7 and (b) pelitic granulite sample S18.
Table caption
1055 1056 1057
1058 1059
1060 1061
1062 1063
1064 1065
1066 1067
1068
Table 1. Representative compositions of garnet (cations are calculated based on 12 oxygens). Table 2. Representative compositions of orthopyroxene (cations are calculated based on 6 oxygens). Table 3. Representative compositions of biotite (cations are calculated based on 11 oxygens). Table 4. Representative compositions of plagioclase (cations are calculated based on 8 oxygens). Table 5. The P–T conditions of different metamorphic stages of the representative pelitic granulites of the Huashan Metamorphic Complex. Table 6. SIMS U–Pb geochronological data of zircons separated from the representative pelitic granulites of the Huashan Metamorphic Complex. Table 7. Summary of metamorphic ages for the Taihua Metamorphic Complex.
1069
49
100°
105°
110°
115°
125°
120°
130°
Abbreviations for metamorphic complexes in Fig.1(a):
Changchun
(a)
SJ
0
200 400 km
Duolun
Bayan Obo WC
GY
40° AL
Yinshan Block HL
WL JP
NH
40°
WD JN XH MY HA Khondalite Belt EH Beijing QL HS WT FP
Xi ' An
LG Pyeonrang
SL
EASTERN BLOCK
WESTERN BLOCK LL Taiyuan ZH Ordos Block 35°
NL
Gyeonggi
ES 35°
TRANS - NORTH WS CHINA OROGEN ZT DF
TH Hidden basement in the Eastern and Western Block
Xinyang Shanghai
Exposed basement in the Eastern and Western Block Hidden basement in the Paleoproterozoic orogens
30°
Exposed basement in the Khondalite Belt in the Western Block
Wuhan
Exposed basement in the Trans-North China orogen Exposed basement in the Jiao-Liao-Ji Belt in the Eastern Block Major fault
115°
110° 10´
109° 45´
125°
120°
110° 15´
110° 30´
Huayin
(b)
Huaxian
AL – Alashan; CD – Chengde; DF – Dengfeng; EH – Eastern Hebei; ES – Eastern Shandong; FP – Fuping; GY – Guyang; HA – Huai'an; HL – Helanshan; HS – Hengshan; JN – Jining; LG – Langrim; LL – Lüliang; MY– Miyun; NH – Northern Hebei; NL – Northern Liaoning; QL – Qianlishan; SJ – Southern Jilin; SL – Southern Liaoning; TH – Taihua; WD– Wulashan-Daqingshan; WL– Western Liaoning; WS – Western Shandong; WT – Wutai; XH – Xuanhua; ZH – Zanhuang; ZT – Zhongtiao.
Tongguan
N
110° 45´ 0 10000m
34° 30´
34° 30´ S37
Arth 1
S7
Arth 2
Arth 1
S18
S25
Pt 1 xl 3
34° 00´
110°30´
110°15´ Lower Taihua Group (Arth 1 )
Upper Taihua Group (Arth 2 )
Upper Xiong'er Group
Proterozoic granite
Μesozoic granite
Sample location
110°45´
34° 00´
Fig. 1
( a)
(b)
Bt 2
Opx 2
Opx 2 Opx 3 Bt 2
Bt 1 Ilm 1
Bt 2 Pl 3 +Bt 3
Grt 2
Grt 2
Qz 1
Bt 1
Bt 3 +Pl 3
Pl 1
Opx 2 Bt 2
1000µm
Opx 2
(c)
(d)
Bt 2
Opx 2
Bt 2
Opx 2
Pl 2 Pl 3 +Bt 3
Bt 2 +Opx 2 +Pl 2
Grt 2
1000µm
St 1
Qz 1 +Pl 1 +Bt 1 Opx 3 +Bt 3 +Pl 3
Grt 2 Bt 1 Pl 1 +Bt 1 +Qz 1
Ap 1
Pl 3 +Bt 3
Opx 2
2000µm
Pl 2 +Bt 2
2000µm
Fig. 2
(a) S18
Fe 500µm
Mg 500µm
Ca 500µm
Mn 500µm
Mg 500µm
Ca 500µm
Mn 500µm
Mg 1 mm
Ca 1 mm
Mn 1 mm
(b) S25
Fe 500µm
(c) S37
Fe
1 mm
Fig. 3
(a) 0.8
S18
0.6
0.4
Xalm
Xpyr
Xgros
Xsps
Fe/(Fe+Mg)
0.2
0.0 -2 0rim 246
12
222426 core2830 34 384042 46485052 rim
(b) 0.8
S25
0.6
0.4
0.2 Xalm
Xpyr
Xgros
Xsps
Fe/(Fe+Mg)
0.0 -2 0rim 2 4 6 8 101214161820222426 485052 core28303234363840424446rim
(c) S37 0.8
0.6
0.4
Xalm
Xpyr
Xgros
Xsps
Fe/(Fe+Mg)
0.2
0.0 -20 rim 2 4 6 810121416182022242628core 3032343638404244464850525456 586062 rim
Fig. 4
(a)
(b) 10
10 M2:730°C 7.2kbar (GBPQ) M2:760°C 6.8kbar (GOPQ) M3:670°C 5.0kbar (GBPQ) 8
S18 8
EA
M2:730°C 7.0kbar (GBPQ) M2:760°C 6.8kbar (GOPQ) M3:680°C 4.2kbar (GBPQ) M3:570°C 4.1kbar (GOPQ) EA M2
M2
Ky
Am
6
6
Ky
Gr
Sil
Am
M3
Gr
Sil
4
M3
4 And
And
2
2 500
600
700
800
900
500
600
700 T (°C)
T (°C) (c)
S25
800
900
(d) 10
10
S18 S25 S37
S37 M2 8
8
EA
Gr EA
6
Am
Ky
Ky
M3
M1
6 Gr
4 And
Sil
Sil
Am
M1:520~530°C (Ti in Bt) M2:740°C 8.6kbar (GBPQ) M2:810°C 7.3kbar (GOPQ) M3:740°C 6.4kbar (GBPQ)
4 And 2
2 500
600
700 T (°C)
800
900
500
600
700
800
900
T (°C)
Fig. 5
NCKFMASHT 10000
Na 2 O CaO K 2 O FeO MgO Al 2 O 3
SiO 2 H 2 O TiO 2
3.94 3.15 2.38 9.93 5.87 17.69 52.64 0.56 0.85
(wt % ) Opx Bt Pl Grt Kfs Ilm Qz Liq Opx Bt Pl Grt Kfs Ilm Liq
Opx Bt Pl Grt Kfs Qz Ru
8400
0 . 27
0 . 25 Opx Bt Pl Grt Kfs Qz
0 . 29
M2
Opx Bt Pl Grt Kfs Liq
0 . 06
0 . 05
0 . 65 Opx Bt Pl Grt Kfs Ilm Qz Ru
6800
0 . 67
Opx Bt Pl Grt Kfs Ilm Qz
0 . 69 0.70
5200
M3
Opx Bt Pl Kfs Qz Opx Bt Pl Crd Kfs Liq
3600
Opx Bt Crd Pl Grt Kfs Ilm Qz
Opx Bt Pl Crd Kfs Qz Liq Opx Bt Pl Crd Grt Kfs Qz Opx Bt Pl Crd Ilm
Opx Bt Pl Crd Kfs Qz
Opx Bt Pl Crd Kfs Qz Ilm
Opx Bt Pl Crd Kfs Ilm Qz
Opx Bt Pl Crd Kfs Ilm
2000 500
600
800
700
900
1000
T ( °C ) X Gr os = Ca/(Ca+Fe+Mg) of garnet
X Al m = F e /(Ca+Fe+Mg) of garnet
X P yr = Mg/(Ca+Fe+Mg) of garnet
Fig. 6
(a) S7 1828±6 03 04 1842±7
05 1822±9
26 1837±6
1854±3 06
17 1826±7
1832±5 07
25 1848±2
100µm
(b) S18
01 2507±9
07 1831±32
08 2572±7
2434±20 11 1868±25 12
1821±13 19 18
20 21 2402±8 1842±16
1816±18 100µm
Fig. 7
2400
0.44
(a) S7
0.40
upper intercept age: 1824±13Ma (MSWD = 0.78)
(b) S18
0.5
2600
upper intercept age: 1818±22Ma (MSWD = 0.36)
2200
2400 upper intercept age: 2547±47Ma (MSWD = 0.94)
0.4 2000
2000
0.36 207
weighted mean Pb/ Pb age: 1846±6Ma (MSWD = 8.4 , n=23) 2 07
1800
0.32
20 6
206
weighted mean Pb/ Pb age: 1823±8Ma (MSWD = 0.99 , n=14)
0.3 1600
lower intercept age: 1792±310 Ma (MSWD = 0.94)
0.2
0.28 3.5
4.5
5.5
6.5 207 Pb/ 2 3 5 U
7.5
8.5
9.5
2
4
6 207
8 Pb/ 2 3 5 U
10
12
14
Fig. 8
1070
Table 1. Representative compositions of garnets (cations are calculated based on 12 oxygens). Grt2
1071 1072 1073 1074
Grt3
Sample
S18 n=46
S25 n=34
S37 n=58
S18 n=3
SiO2
37.14
37.15
36.67 36.84
37.05 36.51
TiO2
0.02
0.02
0.04
0.04
Al2O3
21.09
21.71
21.46 20.94
21.27 21.27
FeO MnO MgO CaO
31.96 0.96 7.05 2.17
29.09 0.69 10.50 0.62
28.33 0.69 8.55 3.73
31.71 0.89 8.27 0.50
0.03 33.86 1.04 6.11 1.62
S25 n=5
S37 n=3 0.03 30.77 1.05 7.27 2.80
Na2O
0.02
0.02
0.01
0.03
0.03
0.04
K2O
0.01
0.01
0.01
0.02
0.02
0.01
Cr2O3
0.00
0.00
0.00
0.00
0.00
0.00
Total Si Ti Al
100.43 2.90 0.00 1.94
99.80 2.86 0.00 1.97
99.49 2.847 0.003 1.964
100.48 2.90 0.00 1.94
99.77 2.90 0.00 1.96
99.74 2.86 0.00 1.96
Fe2+
1.85
1.58
1.526 1.99
1.84
1.72
3+
Fe
0.26
0.32
0.340 0.26
0.25
0.32
Mn Mg Ca Na K Cr Total
0.06 0.82 0.18 0.00 0.00 0.00 8.02
0.05 1.20 0.05 0.00 0.00 0.00 8.03
0.045 0.990 0.310 0.002 0.001 0.00 8.03
0.07 0.72 0.14 0.00 0.00 0.00 8.02
0.06 0.96 0.04 0.00 0.00 0.00 8.02
0.07 0.85 0.23 0.01 0.00 0.00 8.03
XAlm
0.63
0.55
0.53
0.68
0.63
0.60
XPyr
0.28
0.42
0.34
0.25
0.33
0.30
XGros
0.06
0.02
0.11
0.05
0.01
0.08
XSps
0.02
0.02
0.02
0.02
0.02
0.02
XFe
0.69
0.57
0.61
0.74
0.66
0.67
XAlm = Fe2+/(Fe2+ + Mg + Mn + Ca); XPyr = Mg/(Fe2+ + Mg + Mn + Ca); XGros = Ca/(Fe2+ + Mg + Mn + Ca); XSps = Mn/(Fe2+ + Mg + Mn + Ca); XFe(g) = Fe2+/(Fe2+ + Mg). Ferric irons are determined according to the method of Droop (1987). Table 2. Representative compositions of orthopyroxene (cations are calculated based on 6 oxygens). Opx2 Sample
S18 n=9
Opx3 S25 n=6
S37 n=12
S25 n=3
SiO2
50.51
50.38
51.30
49.87
TiO2
0.07
0.06
0.06
0.06
Al2O3
3.23
5.08
2.32
5.00
FeO
29.20
24.47
25.91
23.09
50
MnO MgO CaO
0.16 17.44 0.11
0.13 20.41 0.01
0.16 20.14 0.17
0.09 21.15 0.01
Na2O
0.03
0.02
0.01
0.03
K2O
0.01
0.01
0.01
0.01
Cr2O3 Total Si Ti Al
0.01 100.76 1.92 0.00 0.14
0.00 100.57 1.88 0.00 0.22
0.02 100.10 1.93 0.00 0.10
0.02 99.32 1.87 0.00 0.22
Fe2+
0.92
0.74
0.79
0.68
3+
Fe
0.01
0.03
0.03
0.04
Mn Mg Ca Na K Total
0.01 0.99 0.00 0.00 0.00 4.00
0.00 1.13 0.00 0.00 0.00 4.00
0.01 1.13 0.01 0.00 0.00 4.00
0.00 1.18 0.00 0.00 0.00 4.00
0.52
0.61
0.59
0.63
XMg 1075 1076 1077 1078 1079
2+
XMg = Mg/(Mg + Fe ). Ferric irons are determined according to the method of Droop (1987).
Table 3. Representative compositions of biotite (cations are calculated based on 11 oxygens). Bt1 Sample
Bt2
S18 n=5
S25 n=3
SiO2
37.01
38.23 38.03
37.01 37.66
37.68 36.83
36.93 37.41
TiO2
3.82
4.41
4.43
3.76
3.92
Al2O3
16.12
16.07 16.31
15.92 16.06
16.15 15.82
15.77 15.78
FeO MnO MgO CaO Na2O
17.88 0.03 12.17 0.02 0.42
10.00 0.02 16.68 0.04 0.57
15.65 0.04 14.57 0.01 0.17
17.39 0.02 11.97 0.00 0.24
13.80 0.02 14.45 0.00 0.45
14.46 0.02 14.11 0.02 0.36
17.85 0.02 11.62 0.00 0.26
15.35 0.02 13.89 0.01 0.41
17.10 0.01 12.68 0.02 0.32
K2O
10.01
8.39
8.94
9.28
8.98
8.91
9.34
8.53
8.70
Cr2O3
0.01
0.05
0.03
0.02
0.02
0.03
0.03
0.05
0.04
Total Si Ti Al
97.48 2.75 0.21 1.41
94.45 2.79 0.24 1.38
95.77 2.81 0.11 1.42
96.28 2.76 0.25 1.40
95.53 2.78 0.23 1.40
95.50 2.79 0.21 1.41
96.24 2.76 0.25 1.40
94.87 2.76 0.22 1.39
95.52 2.80 0.20 1.39
Fe2+
1.11
0.61
0.97
1.09
0.85
0.89
1.12
0.96
1.07
3+
0.00
0.00
0.00
0.00
0.00
0.00
0.00
0.00
0.00
Fe
S37 n=3 2.03
S18 n=12
Bt3 S25 n=6
S37 n=11
4.09
51
S18 n=6 4.46
S25 n=6
S37 n=3 3.47
Mn Mg Ca Na K Total XFe 1080 1081 1082 1083
0.00 1.35 0.00 0.06 0.95 7.84
0.00 1.81 0.00 0.08 0.78 7.70
0.00 1.61 0.00 0.02 0.84 7.79
0.00 1.33 0.00 0.04 0.88 7.75
0.00 1.59 0.00 0.06 0.84 7.75
0.00 1.56 0.00 0.05 0.84 7.75
0.00 1.30 0.00 0.04 0.89 7.75
0.00 1.55 0.00 0.06 0.81 7.76
0.00 1.41 0.00 0.05 0.83 7.75
0.45
0.25
0.38
0.45
0.35
0.36
0.46
0.38
0.43
2+
2+
XFe = Fe /(Fe + Mg) Table 4. Representative compositions of plagioclase (cations are calculated based on 8 oxygens). Pl1
1084 1085 1086
Pl2
Sample
S18 n=3
S25 n=3
SiO2
58.41
TiO2
S37 n=3
Pl3
S18 n=18
S25 n=11
64.46 60.15
61.74
0.02
0.00
S18 n=6
S25 n=9
64.29 54.00
61.28
63.87 53.43
0.01
0.01
0.01
0.01
Al2O3
24.78
22.13 24.77
23.73
21.85 28.44
23.78
21.98 28.55
FeO MnO MgO CaO
0.53 0.02 0.00 7.75
0.13 0.00 0.01 3.43
0.32 0.00 0.00 7.28
0.07 0.01 0.01 6.17
0.05 0.00 0.00 3.33
0.12 0.01 0.01 11.87
0.15 0.01 0.00 6.24
0.23 0.01 0.00 3.52
0.13 0.00 0.01 12.61
Na2O
7.62
9.72
7.90
8.23
9.76
5.34
8.16
9.69
4.96
0.00
S37 n=9 0.01
S37 n=3 0.01
K2O
0.09
0.04
0.04
0.20
0.08
0.05
0.19
0.05
0.04
Cr2O3
0.00
0.02
0.00
0.01
0.01
0.01
0.00
0.01
0.00
Total Si Ti Al
99.23 2.64 0.00 1.32
99.94 2.84 0.00 1.15
100.44 2.68 0.00 1.30
100.17 2.74 0.00 1.24
99.39 2.85 0.00 1.14
99.87 2.45 0.00 1.52
99.81 2.73 0.00 1.25
99.37 2.84 0.00 1.15
99.75 2.43 0.00 1.53
Fe3+
0.02
0.00
0.01
0.00
0.00
0.00
0.01
0.01
0.00
Mn Mg Ca Na K Cr Total
0.00 0.00 0.38 0.67 0.01 0.00 5.03
0.00 0.00 0.16 0.83 0.00 0.00 5.00
0.00 0.00 0.35 0.68 0.00 0.00 5.02
0.00 0.00 0.29 0.71 0.01 0.00 5.00
0.00 0.00 0.16 0.84 0.00 0.00 5.00
0.00 0.00 0.58 0.47 0.00 0.00 5.03
0.00 0.00 0.30 0.71 0.01 0.00 5.00
0.00 0.00 0.17 0.83 0.00 0.00 5.00
0.00 0.00 0.61 0.44 0.00 0.00 5.02
XAn
0.36
0.16
0.34
0.29
0.16
0.55
0.29
0.17
0.58
Xab
0.64
0.83
0.66
0.70
0.84
0.45
0.70
0.83
0.41
XOr
0.00
0.00
0.00
0.01
0.00
0.00
0.01
0.00
0.00
Table 5. The P-T conditions of different metamorphic stages of the representative pelitic granulites of the Huashan Metamorphic Complex. Sample
Prograde stage (M1 ) 52
Peak stage (M2)
Retrograde stage
(M3) T (°C)
P (Kb ar)
Method
S18
S25
520– 530
S37
1087 1088 1089
4–5
Ti-in-bi otite geother momete r
T (° C)
P (Kb ar)
73 0 76 0 81 0 73 0 76 0 74 0
Meth od
8.6
GBP 68 Q 0 GOP Q 63 0 5 GBP 68 Q 0 GOP 57 Q 0 GBP 74 Q 0
7.3
GOP Q
7.2 6.8 7.8 7 6.8
81 0
T (° C)
P (Kb ar)
Metho d
5.1
GBPQ
Pseudo section 4.2
GBPQ
4.1
GOPQ
6.4
GBPQ
Table 6. SIMS U-Pb geochronological data of zircons separated from the representative pelitic granulites of the Huashan Metamorphic Complex. Spot
Content (ppm)
Th/ U
Istopic ratios 207
U
Th
Pb
S7-1
287
11
105
S7-2
1773
50
714
S7-3
337
15
124
S7-4
297
19
111
S7-5
149
21
57
S7-6
1898
45
732
S7-7
546
26
217
S7-8
291
11
108
S7-9
799
30
305
0.0 4 0.0 3 0.0 5 0.0 6 0.1 4 0.0 2 0.0 5 0.0 4 0.0 4
Pb/206 Pb
0.1113 0.1152 0.1117 0.1126 0.1114 0.1134 0.112 0.1114 0.1133
206
1σ 0.3 6 0.1 7 0.3 4 0.4 1 0.4 9 0.1 9 0.3 0.4 3 0.2 2 53
Age/(Ma)
Pb/23 U
1σ
0.3276
1.5
5.0278
0.3585
1.5
5.6959
0.327
1.5
5.0385
0.3309
1.5 3
5.1384
0.3315
1.5
5.089
0.3443
1.5
5.3812
0.353
1.5
5.4508
0.3308
1.5
5.0828
0.3391
1.5
5.2958
8
207
Pb/23 U
5
207
1σ 1.5 4 1.5 1 1.5 4 1.5 8 1.5 8 1.5 1 1.5 3 1.5 6 1.5 2
Pb/206 Pb
1 σ
1821
7
1883
3
1828
6
1842
7
1822
9
1854
3
1832
5
1823
8
1852
4
S7-1 0 S7-1 1 S7-1 2 S7-1 3 S7-1 4 S7-1 5 S7-1 6 S7-1 7 S7-1 8 S7-1 9 S7-2 0 S7-2 1 S7-2 2 S7-2 3 S7-2 4 S7-2 5 S7-2 6 S7-2 7 S7-2 8 S181 S182 S18-
157
5
58
1798
56
699
256
9
98
321
15
120
193
48
91
457
22
174
3003
195
117 4
237
10
88
144
69
77
1183
50
455
277
10
103
259
8
96
1841
97
699
264
9
99
278
11
103
2633
134
102 9
404
14
144
595
220
291
326
122
156
168
48
98
124
19
47
54
12
22
0.0 3 0.0 3 0.0 3 0.0 5 0.2 5 0.0 5 0.0 7 0.0 4 0.4 8 0.0 4 0.0 4 0.0 3 0.0 5 0.0 4 0.0 4 0.0 5 0.0 3 0.3 7 0.3 8 0.2 9 0.1 5 0.2
0.1114 0.1127 0.1121 0.111 0.123 0.1127 0.1133 0.1116 0.1422 0.1131 0.1114 0.1128 0.1139 0.111 0.1114 0.113 0.1123
0.5 1 0.1 8 0.4 1 0.4 8 0.6 9 0.4 1 0.1 6 0.3 8 0.4 8 0.2 6 0.4 9 0.3 6 0.1 3 0.3 6 0.3 7 0.1 4 0.3 6
0.3278
1.5 4
5.0327
0.3467
1.5
5.3887
0.3415
1.5 1
5.2769
0.3326
1.5
5.0922
0.3886
2.1 9
6.5924
0.3372
1.5
5.2394
0.3455
1.5
5.3985
0.331
1.5
5.0932
0.4181
1.5 1
8.2006
0.3418
1.5
5.3314
0.333
1.5
5.1126
0.3302
1.5
5.137
0.3361
1.5 4
5.2778
0.335
1.5
5.1266
0.3304
1.5
5.0734
0.3465
1.5 9
5.399
0.3188
1.5
4.9365
1.6 2 1.5 1 1.5 6 1.5 8 2.2 9 1.5 6 1.5 1 1.5 5 1.5 9 1.5 3 1.5 8 1.5 5 1.5 5 1.5 4 1.5 5 1.6 1.5 5 1.5 1 1.5 9
1822
9
1844
3
1834
7
1816
9
2001
1 2
1843
7
1853
3
1826
7
2255
8
1850
5
1822
9
1845
7
1862
2
1816
7
1822
7
1848
2
1837
6
2113
4
2102
9
9
0.1311
0.2
0.3927
1.5
7.0991
0.1303
0.5 1
0.3834
1.5 1
6.8877
0.4659
1.5
10.594 7
1.6
2507
0.3307
1.5
5.0458
1.6
1810
0.3416
1.5
5.2085
1.8
1809
0.1649 0.1107 0.1106
0.5 5 0.5 4 1.0
54
1 0 1
3 S184 S185 S186 S187 S188 S189 S1810 S1811 S1812 S1813 S1814 S1815 S1816 S1817 S1818 S1819 S1820 S1821 S1822 S1823 1090 1091 1092
25
9
10
58
13
22
85
8
32
13
5
6
218
84
142
178
71
117
99
8
38
226
73
123
28
6
10
215
82
144
48
10
19
114
44
73
251
121
172
42
10
16
74
13
29
71
14
28
627
5
321
45
8
18
81
7
31
51
9
20
3 0.3 6 0.2 2 0.1 0.3 6 0.3 8 0.4 0.0 8 0.3 2 0.2 2 0.3 8 0.2 1 0.3 8 0.4 8 0.2 5 0.1 7 0.2 0.0 1 0.1 7 0.0 9 0.1 7
0.1106 0.1109 0.1128 0.1119 0.1715 0.174 0.1114 0.1579 0.1142 0.1729 0.1107 0.1737 0.1803 0.1112 0.111 0.1113 0.155 0.1126 0.1127 0.1104
6 1.2 1 0.7 7 0.6 2 1.7 8 0.4 2 0.2 9 0.5 8 1.1 7 1.3 8 0.3 1 0.9 7 0.6 7 0.2 8 0.9 4 1.0 2 0.7 2 0.4 5 0.8 6 0.7 5 0.8 4
0.3329 0.3281 0.3308 0.3353 0.5065 0.5085 0.3387 0.4326 0.3061 0.5191 0.3379 0.4952 0.5207 0.3161 0.3333 0.3382 0.4424 0.3404 0.3326 0.3295
2 1.5 2 1.5 6 1.5 2 1.5 6 1.5 1 1.5 1.5 4 1.5 2 1.5 2 1.5 1.5 1 1.5 1 1.5 1.5 1 1.5 1 1.5 1 1.5 1.5 1 1.5 2 1.6 4
5.079 5.0182 5.1466 5.1753 11.973 3 12.199 9 5.2044 9.4193 4.8222 12.373 5.1584
1.8
11.858 1 12.941 9
1.6 5 1.5 3 1.7 8 1.8 3 1.6 7 1.5 7 1.7 4
4.8488 5.1026 5.1901 9.4533 5.2865
1810 1815 1845 1831
7
2596
5
1823 2434 1868 2586 1811 2593 2655 1820 1816 1821 2402 1842
1.7
1844
5.0137
1.8 5
1805
Table 7. Summary of metamorphic ages for the Taihua Metamorphic Complex.
9 2 2 1 4 1 1 3 2
2572
5.1707
The data with strikethrough are invalid.
55
5 1.9 4 1.7 4 1.6 4 2.3 6 1.5 7 1.5 3 1.6 4 1.9 2 2.0 5 1.5 4
1 1 2 0 2 5 5 1 8 1 1 5 1 7 1 8 1 3 8 1 6 1 4 1 5
Lushan
Wugang
Luoning
Huashan
Age (Ma)
Sample
Description
TW006/1
garnet-sillimanite gneiss
TWJ358/1
garnet gneissic granitoid
L15
amphibolite
L31
amphibolite
L40 L10 L56
amphibolite amphibolite amphibolite
L51
TTG
L54 L50
TTG gneissic granitoid
L57
amphibolite
L65
amphibolite
L66
amphibolite
HN804
amphibolite
YU19
amphibolite
YU21
amphibolite
YU23
amphibolite
04MC14
amphibolite
C21
amphibolite
C20
amphibolite
C23
metapelite
S2
amphibolite
1844 ± 66 1871 ± 14 1945 ± 25 1920 ± 12 1919 ± 8 1927 ± 7 1918 ± 5 1915 ± 14 1934 ± 7 1928 ± 5 1928 ± 6 1920 ± 17 1960 ± 26 1939 ± 19 1967 ± 32 1958 ± 32 1938 ± 9 1950 ± 20 1940 ± 10 1944 ± 5 1937 ± 11 1823 ± 4
S3
amphibolite
1890 19
S33
metapelite
1941 13
±
S51
amphibolite
1852 23
±
56
±
Method
Source
SHRIMP
Wan et al. (2006)
SHRIMP
Wan et al. (2006)
SIMS
Lu et al. (2013)
SIMS
Lu et al. (2013)
SIMS SIMS SIMS
Lu et al. (2013) Lu et al. (2015) Lu et al. (2015)
SIMS
Lu et al. (2015)
SIMS SIMS
Lu et al. (2015) Lu et al. (2015)
SIMS
Lu et al. (2014)
SIMS
Lu et al. (2014)
SIMS
Lu et al. (2014)
LA-ICP-MS
Jiang et al. (2011)
LA-ICP-MS
Jiang et al. (2011)
LA-ICP-MS
Jiang et al. (2011)
LA-ICP-MS
Jiang et al. (2011)
LA-ICP-MS
Diwu et al. (2014)
SIMS
Chen et al. (2015)
SIMS
Chen et al. (2015)
SIMS
Chen et al. (2015)
SIMS
Wang et al. (2012)
SIMS
Wang et al. (2012)
LA-ICP-MS
Wang et al. (2012)
LA-ICP-MS
Wang et al. (2012)
S24a
metapelite
1869 39
±
S25
metapelite
1848 20
±
S34
metapelite
1961 26
±
xql0912-2
gneissose pegmatitic granite
1866 19
±
xql0915-2
granitic veins
1881 24
±
THH08-62
granitic gneiss
1918 17
±
S1
amphibolite
S41
LA-ICP-MS
Wang et al. (2013)
LA-ICP-MS
Wang et al. (2013)
LA-ICP-MS
Wang et al. (2013)
LA-ICP-MS
Yu et al. (2013)
LA-ICP-MS
Yu et al. (2013)
LA-ICP-MS
Huang et al. (2013)
1846 ± 8
SIMS
Wang et al. (2014)
amphibolite
1866 17
±
SIMS
Wang et al. (2014)
08LF2
paragneiss
1928 15
±
LA-ICP-MS
Diwu et al. (2014)
S7
pelitic granite
1846 ± 6
SIMS
this study
S18
pelitic granite
1823 ± 8
SIMS
this study
1093 1094 1095
57
1096 1097
● Clockwise P–T–t paths were retrieved from the Mts. Huashan
1098
pelitic granulites.
1099
● SIMS U–Pb dating of metamorphic zircons reveal the
1100
metamorphic ages of 1.85–18.2 Ga.
1101
● The tectonothermal evolu(on of the TNCO started as early as
1102
~1.97 Ga and lasted as late as 1.80 Ga.
1103
● An eastward subduc(on model for the TNCO is suggested in
1104
this study.
1105 1106
58