The Rb-Sr isotopic record in Taiwan gneisses and its tectonic implication

Tectonophysics, 183 (1990) 129-143 Elsevier Science Publishers B.V.. Amsterdam

129

The Rb-Sr isotopic record in Taiwan gneisses and its tectonic implication * Ching-Ying

Lan, Typhoon

Institute of Earth Sciences, Academia

Lee ** and Cbibming

Sinica and Institute of Geology, National 10764 Taipei (Taiwan, China)

Wang Lee

Taiwan University, P.O. Box 23-59,

(Received February 10,1989; revised version accepted October 10, 1989)

ABSTRACT Ching-Ying Lan, Typhoon Lee and Chihming Wang Lee, 1990. The Rb-Sr isotopic record in Taiwan gneisses and its tectonic implication. In: J. Angelier (Editor), Geodynamic Evolution of the Eastern Eurasian Margin. Tectonophysics, 183: 129-143.

A Rb-Sr isotopic study of six Taiwan gneiss bodies has revealed three thermal events at ca. 90 Ma, ca. 40 Ma and < 12 Ma B.P. The 90 Ma event was identified by the Rb-Sr system for the first time. Applying the estimated closure temperatures for the Rb-Sr and other isotopic systems, we suggest that the 90 Ma event reached a temperature of higher than 500°C and therefore was probably the heating event that occurred under upper amphibolite facies condition, that produced the granitoids. Some whole-rock samples from areas several square kilometres in size provide isochrons of this age suggesting that the granitoids were produced by local scale melting. The latter two events produced greenschist facies metamorphism, with the 40 Ma event occurring at temperatures higher than those which occurred during the < 12 Ma event. Both events were more intense in the southern gneiss bodies. Thus either the southern bodies were buried deeper during the last 40 Ma or the tectonic activities were more intense in the south for both events. The second alternative is consistent with the fact that the on-going arc-continent collision responsible for the < 12 Ma event was from the south. The biotite cooling ages for the < 12 Ma event seem to be older in the west within two gneiss bodies. This fact could be explained by incomplete resetting by decreasing temperature toward the west, or by a real difference in cooling ages and hence slower uplift toward the west. When biotite cooling age data are combined with fission-track data, it may be demonstrated, in agreement with previous stratigraphic observations, that the rate of uplift due to the on-going collision has been accelerating during the past 2 m.y.

Introduction

major

Taiwan is situated at the junction between the Ryukyu and Luzon arcs on the eastern margin of the Eurasian continental plate bordering the Philippine Sea plate. It is a site of active collision between the Luzon Arc and Eurasia, which caused rapid uplift and erosion. This island is an example of continental growth via repeated accretion of exotic terranes (see the review by Ernst and Jahn (1987), for example). A potentially important recorder of these tectonic events is the gneisses which constitute a

* IES contribution 609 ** Also: Department of Physics, National Taiwan University. 0040-1951/90/$03.50

0 1990 - Elsevier Science Publishers B.V.

component

of the Taiwan

pre-Tertiary

metamorphic basement (Yen, 1960). Palaeontological evidence (Yen et al., 1951; Yen, 1953; Lee, 1984) and carbon (Yui, 1987) and Sr (Jahn et al., 1984) isotopic data on the marble sequence in the basement complex together with other geological data suggest that the crustal evolution of Taiwan probably began with elastic and carbonate deposition during Permo-Triassic times (255-200 Ma). Since then this basement has experienced several tectonothermal events, for which the chronological data are summarized in Table 1. The most recent event is the on-going arc-continent collision which is evident from the less than 2 Ma fission-track ages (Liu, 1982) and from the less than 10 Ma biotite ages determined using the Rb-Sr (Jahn et al., 1986; Lan et al., 1986a) and the K-Ar meth-

130

TABLE

C.-Y. LAN

ET At.

1

Summary

of radiometric

Rock type

ages (Ma) of gneisses Rb-Sr

a

and amphibolite

enclaves

from the basement “OAr_ 39Ar

K-Ar

C.7.8

complex U-Pb

of Taiwan

d.4

Kiyoku gneiss body (Ki) Gneiss

Amphibolite

enclave

kO.1

(B) 4

40.1

+2.0

(B) 4

gneiss body (F) 6.5 8.1 8.9 10.6 11.2 44.8 91.5 enclave 20.5

Tachoshui gneiss body (T) Gneiss

Chipan gneiss body (C) Gneiss

(B) 4 (B) 4 (B) (M)

39.7

Fanpaochiemhan Gneiss

Amphibolite

Fission es3 track

0.37 + 0.05 (A)

Yuanioushnn gneiss body (Y) Gneiss 35.0 k4.8 37.0 f3.6 42.0 +1.5 79.1 +4.1

Pegmatite

r.h

-0.04 2.1 7.3 8.4 8.4

2.5 3.5 3.9 6.4 10.3 11.6

+0.4 *0.4 kO.3 +0.4 +0.5 +1.8 +8.5 50.6

(B) (B) (B) (B) (B) (M) (M) (B)

30.5 33.0

+I.5 +2.0

(B) 5 (B) ’

33.1 33.5 35.4 39.0 57.8 63.9 78.0 62.0 74.4 76.7 76.8 85.2 86.0

*1.7 +1.8 +0.8 *2.8 +3.2 f3.5 +3.1 +3.6 *3.4 k3.8 f4.3 k55.0

(B) 4 (W) 5 (B) 5 (B) * (B) ’ (W) 5 (M) 6 (B) 5 (M) 5 (M) ’ (M) 5 (M) ’ (M) ’

82

(H)

92-135

(H)

(B)

38.0 82.5 lt4.1 83.8 +4.2 86.5 +4.3

(H) (W) (W) (W)

88.2

(H) 4

10.8 +0.5

(B) 6

12

f 1.8 (M) 6

46

39.0

4 5 5 5

1.9 (K) 20.8 +0.2(B) 30.4 i 0.2 (B) 32.7 f 0.1 (B) 78-85 (M)

’

85.8 + 1.4 (Z)

0.99 + 0.13 (S)

CM)

+0.01(B) +O.l (B) +0.3 (B) f0.3 (B) kO.4 (B)

+O.l *0.5 kO.3 +0.3 f0.4 +0.5

(B) 4 (B) 4 (B) (B) 4 (B) (B)

4.2 (B) 6.5 *0.3 (B) 9.0 dcO.5 (B) 9.65 + 1.05(B)

4 5 5 *

0.25 k 0.06 (A) 0.45 * 0.04 (A) 0.85 rt 0.10 (Z)

7.7 k 0.1 (B) 8.2 f 0.1 (B)

90.3 f 1.4 (Z)

0.29 0.47 0.48 1.31

f f * *

0.03 0.05 0.06 0.14

(A) (A) (A) (Z)

0.28 0.37 0.40 0.47 0.51 0.53 0.54 0.58

+ f f f + rt f f

0.02 0.05 0.03 0.05 0.06 0.05 0.05 0.07

(A) (A) (A) (A) (A) (A) (A) (A)

a Data from this work (Table 2) and other sources: r Yen and Rosenblum (1964); * Juan et al. (1972); 3 Liu (1982); 4 Jahn et al. (1986); 5 Juang and Bellon (1986); 6 Law (1988); ’ Lo et al. (1988); s Lo (1988). b Abbreviation: (A) = apatite; (B) = biotite; (H) = hornblende; (K) = K-feldspar; (M) = muscovite; (S) = sphene; (W) = whole rock; (Z) = zircon. ’ Integrated and plateau dates by the @Ar- 39Ar incremental heating technique. d Lower intercept of discordia. e Annealing age of 238U spontaneous fission. ’ Integrated age, stepwise heating analysis gave ages between 20 and 72 Ma without a plateau near 40 Ma. K-Ar, Ar-Ar and Rb-Sr were all performed on sample TCS37.

Rb-Sr

ISOTOPIC

RECORD

IN TAIWAN

GNEISSFS

AND

ITS TECTONIC

IMPLICATION

131 24”35’

24”30’

24’20’

0

I

I

I

,

5 I

Schist-slate Sample Rb-Sr

,

,

,

,

IOkn

Boundary Locality

Mineral

Age

in

Ma

Gnelss Marble

24’10’

Schist Village River Highway

24”05’ 121”50’ Fig. 1. Sample locality map showing the six gneiss bodies (stippled areas, modified from Ho, 1986) in the metamorphic basement complex of Taiwan. Rb-Sr mica ages in Ma are shown in the parentheses (biotite-no prefix; muscovite--M; biotite in amphiboiite enclave--A). Ki = Kiyoku; Y = Yuantoushan; F = Fanpaochienshan; T = Tachoshui; C = Chipan; Ka = Kanagan. Sample prefix “TCS’is omitted for bodies F and T. Sample localities of Jahn et al. (1986) are also included, with the prefix “J”. The four geological provinces of Taiwan are shown in the inset: IA = basement complex of the Central Range; ZB = Hsuehshan and Yushan of the Central Range; ZZ= Western Foothills; ZIZ = Coastal Range. Biotite ages in body Y are older than those in the bodies toward the south. The same is true for the muscovite ages. This suggests that the northernmost body was heated less severely in the most recent thermal event. In bodies T and C, the biotite ages are older in the west than in the east. 121’40’

132

C.-Y.

LAN ET AL.

ods (Yen and Rosenblum, 1964; Juan et al., 1972; Juang and BelIon, 1986; Law, 1988; Lo, 1988; Lo

these bodies. Ki is intercalated in the metapelites. Y and F are enclosed in the metapelites and

et al., 1988).

amphibolites,

covered earlier using

The

latter

two

a thermal

event

at around

event

around

the K-Ar

zircons recently,

the presence

dating

and by U-Pb (Jahn

Previous isotopic

un-

of marble

whereas with

T, C and Ka mainly

the marble.

Samples

lected from all six bodies at the localities

dating

Fig. 1. All gneisses

of

has suggested event

around

1988). studies of the Taiwan

at contacts

identified

et al., 1986). More

of a still more ancient

170 + 30 Ma (Jahn,

also

40 Ma. An

90 Ma has been

method

in the gneisses Pb-Pb

methods

composition,

was abundant gneisses,

consisting

two micas together amphibole, absent

have a similar

zircon,

of quartz,

with minor apatite

shown in

mineralogical plagioclase

amounts

and

occur

were col-

and

of garnet,

opaques.

Biotite

in Y, F, T and C, rare in Ka, and

in Ki. These

minerals

probably

formed

in

primarily those of Jahn et al. (1986), were conducted mainly on the two most accessible bodies:

at least two episodes, with an early high-temperature episode under amp~bolite facies conditions

Yuantoushan and Chipan. Furthermore, the RbSr method has been applied to mainly biotite separates and a limited set of whole-rock samples of rather narrow Rb/Sr ratios. We have expanded our study to all the major gneiss bodies with a

as indicated by the paragenesis of the assemblage plagioclase (An,,_,,)-biotite-muscovite-silhmanite-hornblende (brown) in all bodies except Ki (Lo and Wang Lee, 1981; Lan, 1982,1989; Wang Lee et al., 1982; Lan and Wang Lee, 1987), and a later greenschist facies metamorphism char-

wider range of composition (thus a greater range in Rb/Sr ratios). With the wide geographical

acterized by the assemblage rite-epidote-clinozoisite sphene in all bodies.

albite-phengite-chlo(Ps,,_,,)-actinolite-

coverage and the availability of minerals sensitive to different blocking temperatures (particularly muscovite), the purposes of our study were thus: (1) to establish the chronological orders of all tectonothermal events using the Rb-Sr dating

Procedure

method, (2) to better correlate these events with metamorphic episodes previously identified in petrographic studies, and (3) to determine the effect of these events on different isotopic systems for different minerals at distinct locations in order to

We generally follow the procedures described in Lan et al. (1986b). Whole-rock (WR) powder samples were prepared from fresh 1 kg pieces. Mineral samples from the 500-1000 pm fraction

understand the temporal-spatial distribution of peak temperatures and uplift rates. The preliminary results of this study have been presented by Lan et al. (1986a, 1988).

Samples

The granitic gneisses of Taiwan are widely distributed between Tungao and Sanchan on the eastern flank of the northern Central Range (Fig. 1). Six main bodies together with a number of small lenses have been mapped (Yen, 1954). From northwest to southeast, these bodies are Kiyoku (Ki), Yuantoushan (Y), F~pa~~ensh~ (F), Tachoshui (T), Chipan (C) and Kanagan (Ka) (Yen, 1954; Chen, 1963; Wang Lee, 1982). In this paper these abbreviations will be used to denote

for plagioclase, amphibole, biotite and muscovite grains were separated using a magnetic separator and by hand picking. Rb and Sr were separated by the usual cation exchange c~omato~aphy. The s7Rb and s4Sr spikes were separately added to the samples before digestion in HF and HNO, acids. For graphite-bearing gneisses, additional HClO, digestion and filtration against undigested carbonaceous particles was necessary. Isotopic ratios and concentrations of Rb and Sr were determined on our VG354 mass spectrometer. Typically, aliquots containing 300-500 ng of Sr and 30-50 ng of Rb were run. Total blanks were 0.5 ng for Rb and 0.25 ng for Sr. Analytical errors are l-5% for Rb, 0.5% for Sr and l-58 for 87Rb/86Sr. The s7Sr/s6Sr for the NBS987 Sr standard was 0.710226, with a long-term reproducibility of 0.000038 (95% confidence level} per analysis.

Rb-Sr

ISOTOPIC

RECORD

IN TAIWAN

GNEISSES

AND

ITS TECIQNIC

Results Mineral

displayed in isochron diagrams (Figs. 2a-f). No well-defined isochrons were observed, indicating a lack of complete equilibration among different constituent phases during the last metamorphic event(s). Tie lines are drawn connecting the high Rb/Sr phases (biotite and muscovite) with the low Rb/Sr material (plagioclase and whole rock).

ages

The Rb-Sr isotopic results are scald in Table 2. Data on mineral separates were obtained for four gneiss bodies (Y, F, T and C) and are

(a)

Yuantoushan

amiss

Body

(b) c

0.785

Gneiss

Body

0.800

.:I: 79.lf4.1

Fanpaochienshan

.

NA5

0.765

133

IMPLICATION

MB

2806

42.m1.5

k 8 \

0.745

0:

& 6

Ma

Whole

S “,

Rock

Ji 6

V: Biotite

0.725

0.750

A: Plagioclase l

0.705 ”

20

40

60

80

A: Amphibole

0.725

: Muscovite

100

120

140

0

zoo

100

a7Rb/8s Sr

(c)

Fanpaochienshan

0.750

Gneiaa

(d)

Body

/

400

44.8kl.8

I

500

Fanpaochienshan

&&se

0

Body

t I.210

0.740

300

e7Rb/Bg Sr

-Z TCti 94

Ma 1.110

-

L $m

0.730

\ 2 6

0.720

100 8Eb/

(e) 0.765

Tachoshui

150

200

0

50

’ 100

150

‘%r

200

250

300

350

400

450

87Rb/86 Sr

Cneim

(f)

Body

,

Chipan

Gneiss

Body

0.760

//I

~

0.750

.

0.740

-

0.730

-

CP3

f 2

/

CP4

11.6Z.tO.5

P -0.04f0.01

0.705

Ma

’ 0

0.720

I 100

200

300

“Rb/”

400

Sr

500

0.710 0

50

100

150

200

250

300

s7Rb/s6 Sr

Fig. 2. Rb-Sr isochron diagrams for coexisting minerals and/or whole rock in four gneiss bodies (Y, F, T and C) and an amphibolite enclave in F. The mineral ages for the arnp~~~~ enclave sample TCS32C from F (b) near the lower intercept are enlarged in the inset of(b). The ages for muscovite are always older than those for the coexisting biotites in the same body.

134 TABLE Rb-Sr

C.-Y.

LAN

2 data for gneiss and amphibolite

Sample No.

from the Tananao

W.R. or

Weight

Rb

Sr

mineral

(mg)

(ppm)

(ppm)

basement *‘Rb,‘%

complex,

Taiwan

s7sr/%r

*2om

Age

*‘Sr/s%r

(Ma)

(at 90 Ma)

Kiyoku gneiss body (Ki) P20 W.R.

66.3

57.4

213

0.779

0.70909

4

0.70809

P21

25.0

84.4

161

1.51

0.70853

4

0.70660

W.R.

Yuantourhan gnerss body (Y) NA9

W.R.

42.9

7.0

154

0.132

0.70531

4

0.70514

2806

W.R.

54.0

78.6

308

0.738

0.70821

4

0.70727

Biotite

72.8

0.78672

21

0.70802

4

Plagioclase NA5

Muscovite

3.0 278.2

Plagioclase

17.4

NA6A

W.R.

25.0

Na7A

W.R.

19.5

NA8

W.R.

18.0

YG23C

Plagioclase

Fanpaochienshnn gnerss TCS37

body

W.R. Muscovite Plagioclase W.R.

TCS49

3.8

12.5 315 59.8 114 95.8 143 31.9

121 e

71.5

512

142.1

395

3.2 19.2

Plagioclase

373

3.0

64.6 131 19.9

TCS53

W.R.

17.5

TCS90

W.R.

19.9

141

Biotite

70.3

487

TCS94

76.5

W.R.

51.1

148

Biotite

70.3

587

Muscovite

279.1

658

TCS103

W.R.

72.3

131

Biotite

70.5

504

TCSllO

W.R.

27.5

Biotite

70.7

f

99.5 464

W.R.

21.5

Biotite

65.5

Amphibole

67.4

8.3

Plagioclase

1.7

12.6

Tachoshut gnerss TCS14

8.2 612

132 0.059

42.0

+1.5

*

79.1

k4.1

h

0.75294

4

227

0.761

0.71174

4

247

1.33

0.71093

4

193

1.43

0.71146

5

0.70963

197

2.09

0.71179

4

0.70911

392

0.236

0.71150

4

24.4

37.4

0.70922

(F) 137.0

Biotite

TCS32C

32.1 380

155 e 1.5 48.9 559

2.25 198 23.4 0.334

0.71311

4

0.74321

4

11.2

kO.5 c

0.72641

4

44.8

fl.Sb

0.71172

4

249

1.52

0.71155

4

408

0.141

0.71141

4

132

1.67

0.71298

4

202

2.02

0.71328

6

0.80038

5

2.4 149 18.5 4.5 203 3.6 248 16.4 155 13.0 53.6 368

580 2.87 91.8 422 1.87 408 1.16 82.2 0.589 84.5

0.71022

0.70960 0.71084 0.71069 10.6

+0.4

a

0.71292

4

0.72115

10

6.5

,0.4

a

91.5

f8.5

d

8.9

f0.3

’

8.1

f0.4

*

20.5

f0.6

’

1.25833

4

0.71247

4

0.76377

4

0.71177

4

0.72104

4

0.70667

4

0.73026

4

0.446

0.70616

5

0.099

0.70578

4

0.70924

0.71008 0.71029

(T)

body

Biotite Plagioclase

72.6 3.6

470 28.3

2.7 4840

514

0.71114

4

0.017

0.71146

4

- 0.04 f 0.01 c

TCS71

W.R.

42.0

126

171

2.13

0.71189

4

TCS73C

W.R.

20.2

119

248

1.39

0.71106

4

0.70928

TCS88

W.R.

14.9

145

210

1.99

0.71179

4

0.70924

Biotite

70.9

536

W.R.

42.6

140 e

Biotite

70.6

604

HP4 HP5 HP8

Kanagan

ET AL

gneiss

W.R.

52.5

13Se

Biotite

70.2

513

W.R.

17.0

144’

Biotite

10.6

556

body

7.1 151 e 8.6 183 ’ 4.7 174’ 4.4

201 2.68 203 2.18 318 2.39 370

0.71762

4

0.71214

4

0.73611

4

0.71162

4

0.74450

4

0.71178

5

0.75556

9

0.70917

2.1

+0.1

d

8.4

+0.4

’

7.3

+0.3

a

8.4

kO.3 ’

0.70871 0.70883 0.70872

(Ka)

SC1

W.R.

33.6

161

112

4.13

0.71094

4

SC2

W.R.

66.0

113

153

2.15

0.71054

4

0.70779

HP1

W.R.

23.7

137

164

2.40

0.70964

4

0.70656

HP2

W.R.

17.9

2.41

0.70980

4

0.70671

HZ1

W.R.

22.0

151

127

3.43

0.71108

4

0.70669

HZ2

W.R.

21.3

131

190

1.99

0.70930

4

0.70674

80.4

96.2

0.70565

Rb-Sr

ISOTOPIC

TABLE

RECORD

IN TAIWAN

GNEISSES

AND

ITS TECTONIC

135

IMPLICATION

2 (continued)

Sample No.

87Rb/86Sr

W.R. or

Weight

Rb

Sr

mineral

(mg)

(ppm)

(ppm)

180

“Sr/“Sr

*2om

Age

87Sr/86Sr

(Ma)

(at 90 Ma)

Chipan gneiss bo& (C)

CP3 CP4 CL74-42-2

a Rb-Sr

mineral

W.R.

65.8

138

Biotite

10.2

510

W.R.

18.4

141

Biotite

10.6

553

Biotite

41.6

559

Plagioclasee

22.0

59

isochron

2.21

5.6

264

214

1.90

5.0

317

7.6

214

219

age taken from two points

0.620

0.71128

22

0.75448

4

0.71122

4

0.75724

4

0.12325

32

0.71150

10

on the biotite-whole-rock

0.70844 11.6

+0.5

a

10.3

+0.4

=

3.9 *0.3

c

0.70879

tie line, X(87Rb) = 1.42 X 10-r’

yr-‘.

b Same as “a”, but for muscovite-plagioclase. ’ Same as “a”, but for biotite-plagioclase. d Same as “a”, but for muscovite-whole e Concentration ’ Amphibolite

obtained

rock.

using X-ray fluorescence

method,

error

- 5-10%.

enclave in gneiss.

North-------------___South

Mineral ages were calculated from the slopes of these lines. The validity of this approach will be discussed later. The data in Table 2 and Fig. 2 clearly show that the ages for muscovites are always higher than those for the coexisting biotites in the same rock samples (e.g. TCS37 and TCS94 in F). This difference is also true for muscovite and biotite from different rocks in the same gneiss body (e.g. NA5 and 2806 in Y). Also note that in TCS32C, an amphibolite enclave sample from F, the amphibole yielded an age which was older than that for biotite. The temporal distribution of the eighteen mineral ages determined in this work together with seven from Jahn et al. (1986) are summarized in Table 1 and Fig. 3. Except for the enclave sample from F, these 24 ages form three clusters around O-12 Ma, 35-45 Ma and 79-92 Ma, these three clusters are most likely corresponding to distinct thermal episodes. The spatial variation of the mineral ages is shown in Figs. 1 and 3. In the northernmost body (Y) the biotite ages cluster around 40 Ma. In F, T and C they are < 12 Ma. Similarly, the biotite of the amphibolite enclave from Y yielded 40 Ma, which is consistent with the surrounding gneiss. This age is older than the 20.5 Ma biotite age for an enclave in F, which is somewhat older than the

Y

100

I I I

Pb

Sr

Ar

1

b

I

FT 1: r -i-

90

80 70 ‘;t;‘ z

6o 50

El 4

40 30 20 10 0

Fig. 3. Radiometric (Y, F, T and K-Ar

and Ar-Ar

arated

heating

be discerned

mineral

C). Methods

ages found used:

= Ar; fission

events around from the Rb-Sr

Rb-Sr

track = FT. Three clearly

79-92, isotopic

to F, the mica ages in the southern heating

in four gneiss bodies

U-Pb=Pb; 35-45

towards

sep-

and O-12 Ma can

system alone. Compared bodies

for the latter

events have been reset more severely, implying temperature

= Sr;

the south.

two

a higher

136

C.-Y. LAN

7-11 Ma ages for the neighbouring

the biotite the only

ages in the southern

< 12 Ma event

while

the 40 Ma event.

those

This

toward

the south.

in Y registered suggests

event (< 12 Ma)

This trend

may also

be true for the 40 Ma event. The muscovite yielded

a 79.1 Ma age, whereas

Thus,

registered

difference

that the effect of the last thermal increased

gneiss.

bodies

in Y

one of the musco-

vites in F showed a 91.5 Ma age and another

has a

44.8 Ma age. It appears

that the muscovite

Y reflects

of the 90 Ma event while

the influence

ET AL

age in

some of the muscovites in F have been reset by the 40 Ma event. Thus, the effect of the penultimate event (40 Ma) apparently also increased to the south.

Fig. 4. Rb-Sr

whole-rock

isochron

gneiss bodies indicating size (northern Fig.

1) yield

diagram

lens in Ka and southwestern tentative varying

of the F and Ka

that areas several square isochrons

kilometres

comer

of ca. 90 Ma, with

initial “Sr/s6Sr

in

in F, see widely

ratios.

A more subtle trend seems to exist within individual bodies. In T, the three ages for gneisses at the western end are older than the two about 12 km to the east. In C, the two ages in the western end are again older than the four to the east but

84 f 15 Ma (Fig. 4). The initial 87Sr/86Sr ratios for these two tentative isochrons are very different (0.7067 versus 0.7107). implying a lack of regional

the distance is only 3 km. Thus, among the < 12 Ma ages, closure ages in the west appear to be older than those in the east.

isotopic equilibration ture of the protoliths.

and

the heterogeneous

na-

Discussion Whole-rock

data

Twenty-eight whole-rock samples from the six gneiss bodies were measured (Table 2). These data, together with the five data f3r Y and C from Jahn et al. (1986) indicate restricted ranges of 87Rb/86Sr (0.1-4) and of 87Sr/86Sr (0.705-0.714). Each body seems to have distinct Rb/Sr and 87Sr/86Sr values. Regression lines fitted using the method of York (1969) with weighting factors inversely proportional to the errors gave “errorchron ages” between negative and 316 Ma, but none of these lines passes through all data from any single body. Thus, no significance regarding time can be attached to any of the whole-rock ages because no strict isochrons can be established. This implies that isotopic equilibration was not achieved for areas of the size of an entire gneiss body. However, over smaller areas within a single body there is some information regarding time available. All four samples from the northern lens of Ka form a linear array with an age of 90 + 10 Ma. The three samples (37, 103 and 110) from the southwestern corner of F fall on a straight line with an age of

Our study of the Taiwan gneisses has established the following: (1) Rb-Sr mineral ages for muscovite and amphibole are older than those for biotite, (2) three distinct events at < 12 Ma, ca. 40 Ma and ca. 90 Ma can be identified from the mineral ages, (3) the two younger events have affected the northernmost body less severely than the southern bodies, (4) the apparent ages that registered the effect of the last event become progressively younger from the west towards the east within two bodies, and (5) no whole-rock isochrons were found for entire bodies but some subunits several square kilometres in size yield whole-rock isochrons consistent with the 90 Ma event. The interpretation

of mineral ages

The mineral ages obtained in this work correspond to the time which has elapsed since the end of Sr isotopic equilibration (so called “closure”) of the high Rb/Sr (Sr-poor) mineral with the coexisting low Rb/Sr (Sr-rich) material. In a metamor-

Rb-Sr

ISOTOPIC

RECORD

phic terrane

IN TAIWAN

GNEISSES

this age is commonly

the time when the rock cooled acteristic isotopes

closure

through either that

mineral.

This

its closure

Rb/Sr

temperature.

(1) the equilibration the mineral

phase

was not

with the

cooling

composition

phase did not represent

of the high

as

the char-

below which the Sr

cease to exchange

of that

ITS TECTONIC

interpreted

through

not be valid if the isotopic

the low Rb/Sr ratio

temperature

in a mineral

surroundings would

AND

when

age of

it is obvious

only fresh samples, alteration petrographic positions

observation.

are those

The mineralogical

com-

expected greenschist to suspect

but

still

that one or more

of the above assumptions has been violated. A case in point is sample TCS14 from T. Compared

the closure

ferential from

exchange

marble)

because

temperatures.

for the assemblages facies

conditions.

Rb or Sr transport The effect of dif-

with other reservoirs

should

the biotite

not

or

during

under

below

we used

was noticed

equilibrated

so

is not easy to

However,

and no sign of weathering

at low temperature

We have no reason

retained a memory of a previous event, or (2) the two phases exchanged differentially with another reservoir (e.g. fluid). Also, the cooling age would be invalidated if the mineral did not remain closed to the transport of Rb and/or Sr after it cooled through the closure temperature (e.g. via low-temperature alteration). In some samples

lower than closure

it cooled

This may occur if reset

at temperatures

assess, and can be significant.

the initial

was not achieved, totally

137

IMPLICATION

(e.g. fluid

be significant.

This

has such a high Rb/Sr

is

ratio

(> 100) that its Sr is very radiogenic and the surrounding reservoirs (gneiss, schist and marble) generally have low 87Rb/86Sr ( < 4) and non-radiogenic 87Sr/86Sr ratios (about 0.707-0.711). For instance, the use of a tieline between whole-rock and mica instead of between plagioclase and mica would only change the inferred age by less than 0.7 Ma in all cases. Even if we were to use the

to plagioclase, the biotite of this rock has a Rb/Sr ratio 30,000 times higher, yet with a slightly lower

likely value (0.7075) for the marble as the initial Sr ratio for the micas the change in ages would still be only about 1-2 Ma. Therefore, we believe that

s7Sr/86Sr. The tie line between plagioclase and biotite has a negative slope and results in a meaningless age of - 0.04 Ma. The plagioclase has

this problem only causes an uncertainty of about 1 Ma. Within this uncertainty the problem of negative ages is easily removed, and none of the con-

an extremely high Sr content in excess of 4800 ppm and thus would require wholesale exchange

clusions in this paper will be substantially changed. The lack of full isotopic equilibration during low-grade metamorphism subsequent to gneiss formation is a distinct possibility. If the equilibration during the later event was not complete so

to alter its Sr isotopic composition, On the other hand, it is easy to contaminate the biotite, which contains only 2.65 ppm Sr. Therefore, a likely explanation for the negative age is the preferential isotopic exchange of the biotite with a less radiogenie Sr component. The marble surrounding this gneiss body (T) is rich in Sr of the composition 0.7073-0.7078 (Jabn et al., 1984). Infiltrating fluid originating from the marble would be an ideal candidate for the contaminating component. A similar phenomenon has been reported in the Aar massif in the central Swiss Alps by Dempster (1986). Cavazzini (1988) has also considered the problem of isochrons with negative age. It is difficult to know whether a similar fate has befallen other samples to lower their biotite ages. Although care must be exercised in the use of the cooling ages, we should not be prevented from using them provided the uncertainty involved can be estimated. The effect of open system behaviour

that the radiogenic S7Sr accumulated from the earlier event was not entirely lost to the surrounding low Rb/Sr reservoir through exchange and equilibration, an age intermediate between the earlier and later events would be obtained. major factor controlling the equilibration is ably temperature. Extensive investigations setting patterns in contact metamorphic (Hart, 1964) and in Alpine nappes (Jager, have established that the closure (resetting) peratures for the Rb-Sr system are 300 and 500 f 50°C for biotite and muscovite tively. There are additional secondary factors cooling rate, pressure, amount of infiltrating grain size, mineral chemistry and mineral that affect resetting (e.g. Dempster, 1986).

The probof rezones 1979) tem-

k 50°C respecsuch as fluid, texture In our

138

C.-Y.

I.AN

8’1‘Al..

data there are cases demonstrating the importance of secondary control. The two muscovite samples

local melting which produced the granitoids and equilibrated the Sr isotopes in areas several square

from F were from adjacent

areas: one was reset by

kilometres

the 40 Ma event whereas

the other

bodies other than C and Y is needed

the 90 Ma event addition,

and

hence

a range of about

in Y. Similar

were found in F, T and C for the that these spreads

reflect the difference

In

< 12 Ma event.

in time when various

the closure (resetting)

Alternatively,

these

spreads

by the differential Lo (1988) suggested

spreads

are real and truly

cooled through caused events.

reset.

7 Ma existed in biotite

ages for the 40 Ma event It is possible

still recorded

was not

could

samples

temperature. have

been

in size. Further

U-Pb

zircon

To gain insight into the protolith granitoids,

initial

Sr isotopic

work for

to check this. for the Taiwan

ratios were calculated

for all gneiss bodies at 90 Ma B.P. (Table 2). They are highly variable

and scatter

range

determined

from the two tentative

rock isochrons. its own

is essentially

between

0.711. This

0.705 and

the same as that 90 Ma whole-

Each gneiss body seems to posses

characteristic

initial

isotopic

ratios.

Ka

resetting of earlier that the difference

and Ki have low initial ratios of 0.706-0.708, C is intermediate around 0.708-0.709, while T and F

the two biotite ages of Jahn et al. (1986) for C was caused by such differential due to different degrees of chloritization.

have high values of 0.709-0.711. Y covers a particularly large range of 0.705-0.710. These characteristic initial ratios for the granitoids reflect the

We found that the most chloritized samples do show the youngest ages in T and C but not in F. However, in detail, the decrease in ages does not correlate well with either the degree of chloritization or the intensity of exsolution in each body.

heterogeneities in their protoliths and can be interpreted, when combined with additional data (Nd isotopes and REEs), as the result of mixing between juvenile mantle material and recycled continental crust (Lan et al., 1988; Lan, 1989).

We were unable to resolve the question ondary control of age resetting.

Tectonic implication

between reported resetting

The interpretation

of sec-

of whole-rock data

The timing and intensity Taiwan gneisses

The validity of whole-rock pends on whether the gneisses

isochron ages deof the same body

were

and

initially

homogenized,

whether

the

analyzed samples had remained closed throughout later metamorphic episodes and hence record the primary emplacement ages. Jahn et al. (1986) have attempted whole-rock dating on Taiwan granitoids. They noted that two samples from Y fell on a 90 Ma line while the tie line between these two data and two data from C corresponds to a 165 Ma age. However, the limited spread in Rb/Sr and the paucity of samples prevented any firm conclusions. Our more extensive data set does not substantiate their speculations. The only possibly meaningful Sr whole-rock ages we found were 90 and 84 Ma for subunits of Ka and F. Because this agrees with the ca. 90 Ma mineral ages found in F and Y, and particularly because the U-Pb analysis of zircon also established lower intercept ages of around 90 Ma for C and Y (Jahn et al., 1986), we interpret the 90 Ma heating event as causing

Our Rb-Sr

results

of events recorded in the

combined

with all previous

isotopic data are used to determine not only the timing but also the peak temperatures of the metamorphic events recorded in the Taiwan gneisses. In Fig. 3, we plot the chronological data (Table 1) for Y, F, T and C obtained using Pb, Sr and Ar isotopic methods and the fission-track technique. The U-Pb zircon lower intercept ages were around 90 Ma in both Y and C (Jahn et al., 1986). This event is also registered in Y for the K-Ar and Ar-Ar ages for muscovites and hornblende, and for the muscovite Rb-Sr age; for one muscovite Rb-Sr age in F; and for Rb-Sr whole-rock ages for the northern lens of the Ka body and possibly also for the western tip of the F body. The 90 Ma event has been recorded in four out of the six bodies, and hence must have been caused by a regional metamorphism. This event was responsible for most of the zircon crystallization. It has equilibrated the Sr in muscovite, whose resetting

Rb-Sr

ISOTOPIC

TABLE

RECORD

IN TAIWAN

GNEISSES

AND

ITS TECTONIC

IMPLICATION

139

3

Temperature Thermal

and pressure

event

Metamorphic

conditions

for the polymetamorphism

in the Y, F, T and C gneiss bodies

F

Y

T

condition inferred from Sr closure temperature

C

0 > 650°C

-9OMa

> 650°C

> 500°C

-40Ma

300-350°C

400-450°c

r > 300°C

t > 300°C

<12Ma

285-300°C

300-350°C

J

1

Metamorphic -9OMa

condition inferred from other methodr 680-720°C 550-700°C b, 5 kbar 310°C

-40Ma

330-550°C

e, 5 kbar

‘, 2-3.5

kbar

‘, 2-4 kbar

+ 630-725°C

d, 3.5-7.3

kbar -+

+ 420-480°C

d, 4.1-4.5

kbar +

and <12Ma

350-475’C

Closure

temperatures

Rb-Sr

muscovite

K-Ar

muscovite

Rb-Sr

biotite

K-Ar

biotite

i

b, 5 kbar

adopted

4Ot-430°c

300 f 50°C (Jager,

1979).

1979).

Mineral

chemistry

of white mica and Ca-amphibole

Mineral

chemistry

of phengite

Element

(Liou et al., 1981).

geothermometry partition

%,4 kbar

1979).

300 f 50°C (Hunziker,

isotopic

425 f 75°C

1979).

350 f 50°C (Hunziker,

assemblages

Carbon

>

were:

500 f 50°C (Jager,

Mineral

Pyrrhotite

f

thermometry between

and Ca-amphibole

and sphalerite

(Lan, 1989). (Wang

geobarometry

Lee et al., 1982). (Huang,

1979).

(Liu et al., 1987). coexisting

mica and chlorite

(Ernst,

temperature was 500°C. Thus, this event must have caused temperatures in excess of 500°C throughout the entire region, and the peak temperature apparently exceeded that for the greenschist facies but is consistent with that estimated for the amphibolite facies conditions of 550-700°C at 5 kbar (Liou et al., 1981) or 630-725°C at 3.5-7.3 kbar (Wang Lee et al., 1982) based on mineral parageneses in the Y and C bodies (Table 3). Therefore, the 90 Ma event is identified as the high-temperature regional metamorphic episode. The whole-rock data further imply that local partial melting occurred to form the granitoids during this event from heterogeneous protoliths, which probably comprised sediments and oceanic crust in various proportions. The 40 Ma event was registered in Y via the Ar and Sr ages for the biotite. In F it was recorded by the Ar in one muscovite, whereas the Sr age of one muscovite was reset by this event but the other still recorded the 90 Ma event. Muscovites are rare in T and C, and hence were not analyzed; it is not known if the 40 Ma event also affected T and C.

1983).

Ages near 40 Ma have been determined using the Rb-Sr (Jahn et al., 1986) and K-Ar (Juang and Bellon, 1986) methods only for the biotites in Y. The additional K-Ar biotite ages near 60 Ma and 20 Ma lead us to question whether there really was a 40 Ma event or whether these ages are fictitious and represent the incomplete resetting of the 90 Ma event by the most recent event. Our discovery of the 40 Ma Sr age in one muscovite from F together with the recently reported K-Ar ages for the same sample (Law, 1988) provide further evidence for the 40 Ma event. If this had been a partial resetting, the muscovite age should vary between 12 Ma and 90 Ma and there is no reason the Sr age should also be around 40 Ma. However, the Ar-Ar age spectrum of this same muscovite (Lo et al., 1988) does not have a 40 Ma plateau. Thus, the reality of the 40 Ma event outside the Y body still awaits further confirmation. In F, the temperature of this Paleogene event must have been higher than that required to completely reset the K-Ar system (350 + 50°C; Hunziker, 1979), but it barely reached that required to reset the

140

C-Y

LAN

ET AL

Rb-Sr in the muscovite (500 f 50°C). Therefore, 400-450°C may be a reasonable estimate. In Y,

(1987). The increase in 6’“C of the organic matter in the schist zone as compared with the slate zone

because

indicates

reset, 350°C

the Ar ages of the muscovites the temperature during

probably

this event.

that the 40 Ma heating of the greenschist The heating

We therefore

event reached

facies conditions

no more, at least around

were not

remained

zircon

but probably

bodies Y and F.

effect of the youngest and

conclude

the extreme

sphene

ages for

from all four bodies,

a temperature

schist, assuming similar Frey Carbon tween

in the Swiss Alps is valid

isotopic pair F and

Using sphalerite of Y (Huang,

400°C

and

in two schist T gave

by Hoefs

applicable

thermometry

using samples

a temperature

thermometry

for the

estimate

in a and

to Taiwan. the calcitelocated

be-

of 430°C.

in schists just north

1979). Liou et al. (1981) have esti-

and from the K-feldspar Ar age from Y (resetting temperature ca. 200°C; Hart, 1964). In addition, it

mated

has reset the biotite Sr and Ar ages for the three southern bodies while in Y they still reflect the 40 Ma event. Thus, the last event also affected the

Phase petrology and element partitioning in mica and chlorite have been used by Ernst (1983) to estimate the conditions of the greenschist facies metamorphism in C, and have yielded 425 f 75°C

entire region. Its peak temperature was greater than ca. 250°C throughout the entire region so that the tracks in zircon and sphene would be reset (Liu, 1982). have been below in F, T and C in not reset in the

The temperature of the last 300°C in Y but above this view of the fact that biotites former but that they were

event value were in the

latter. In F, this temperature would not have reached beyond 350°C thus avoiding resetting of the Ar in the muscovites. These constraints limit the temperature conditions to that of the mid-range of greenschist facies metamorphism. Of all the published mineral age data on the Taiwan gneiss, only three values fell outside the ranges of the above three events; all three values concern Ar ages for biotites from Y. Two of them lie intermediate between 40 and 90 Ma and the other between 40 Ma and the < 12 Ma event. We are inclined to interpret these three ages as fictitious owing to partial resetting. The last two events were both greenschist facies metamorphism events. The last event reached 250-300°C in Y and 300-350°C in F, while the 40 Ma event reached 300-350°C in Y and 400450°C in F. These temperatures depend on the closure temperature which was estimated elsewhere and which may not be strictly applicable to Taiwan. However, it is gratifying to see that they agree with the estimates based on other methods (Table 3). Carbon isotopic compositions of metasediments have been measured in a transect across the slate/schist boundary by Liu et al.

the

of around

that the temperature

profile (1976)

graphite

event can be

seen in the young (< 2 Ma) fission-track apatite,

below

metamorphism

conditions

of the

greenschist

in Y to be 350-475°C

facies

at 5 kbar.

at 4 kbar. Wang Lee et al. (1982) have derived similar values (420-48O”C, 4.1-4.5 kbar) for C and for T. From Table 3 it is clear that the conditions estimated by Liou et al. (1981) for the greenschist facies metamorphism in Y are applicable only to the Paleogene event and should not be confused with the most recent event. The carbon isotopic temperature is also for the Paleogene event, and was not re-equilibrated in the most recent event. Furthermore, since both events were capable of producing chlorites, it is not surprising that it is difficult to correlate the resetting of the biotite ages with chloritization. The tectonic significance

of the temperature

distribu-

tion Two types of gradient were observed for the youngest event. First, there is the temperature difference between Y and F. The more southerly body (F) seems to have been hotter (> 300°C) than the northern body (Y) (< 3OO’C). Secondly, we found that within bodies T and C the ages in the west are older than those in the east, indicating that the temperature was increasing towards the east. The temperature differences in these two directions may result from the tectonic activity caused by the ongoing arc-continent collision in eastern Taiwan. Such differences may also have resulted from different burial depthsthe overburden may increase towards the east or the south,

Rb-Sr

ISOTOPIC

RECORD

IN TAIWAN

GNEISSES

AND

ITS TECTONIC

which would cause the temperature to increase in these directions. The 40 Ma event seems to have been a more intense event than the < 12 Ma event because it reached higher temperatures. It also showed a temperature increase from Y to F, which is similar to that for the < 12 Ma event. Therefore, perhaps the Paleogene event was also caused by tectonic activity or a difference in burial depth. Jahn et al. (1986) have speculated that the 40 Ma event might have been related to the opening of the South China Sea. Note that the southward increase in temperature found in the gneiss contradicts that inferred from petrographic studies of the neighbouring schist. Chen et al. (1983) noticed that garnet was present in schists near Y, biotite occurred near C, and only chlorite occurred further to the south. They attribute this to a temperature decrease towards the south during greenschist facies metamorphism.

141

IMPLICATION

Uplift 0

(a)

G

Rate

60

T

Gneiss

v

Biotile

Body

e

12

10

8

6 Time

4

2

P*e,e”t

(Ma)

0

(b)

C

0 Gnei,ss

Body

60

360 , 12

I

L__~_I________L_____-~~-~

10

B

The uplift rate in the current mountain building

6 Time

Fig. 5. Uplift rate (mm/yr)

The fission-track ages of apatites have been determined by Liu (1982) for Y, T and C. In each of the three bodies they show an identical range from 0.25 to 0.6 Ma. This corresponds to uplift rates of between 7 and 13 mm/yr for the past 900,000 years. The Holocene rates have been estimated from dating of uplifted corals to be about 5 mm/yr (Peng et al., 1977), while the present rate has been measured with geodetic techniques to be up to 20 mm/yr (Liu, 1987). Using the Rb-Sr cooling ages of the biotites, we can compute the uplift rates in the Pliocene. The possible ranges are between 0.3 and 2.9 mm/yr for T and between 0.5 and 2.5 mm/yr for C (Fig. 5). Jahn et al. (1986) gave a rate of at least 3-4 mm/yr for C. These rates agree with those estimated from sedimentation rates in the Western Foothills of Taiwan dated using pollen, biostratigraphy and palaeomagnetism (Chen et al., 1977; Liew, 1986; Homg et al., 1988). It seems that different methods all suggest a gradual acceleration of uplift rates towards recent times. Note that the uplift rates estimated above assume a geothermal gradient of 30°C/km. However, in Barr and Dahlen’s recent thermal model of the Taiwan thrust belt (1989), the geothermal gradient in the

(mm/year)

r

4

2

Present

(Ma)

for the Central Range based on the

Rb-Sr biotite ages (this study) and fission-track ages of zircon and apatite (Liu, 1982) of the (a) T gneiss body and (b) C gneiss body assuming a geothermal gradient of 30°C/km

and

a surface temperature of 20°C. The adopted closure temperatures for biotite, zircon and apatite are 300*50, 135f20

235+50

and

“C, respectively. An acceleration in the uplift rates from Late Miocene towards Recent is apparent.

basement is expected to be much higher due to internal strain heating and frictional heating on the decollement. If so, the uplift rates based on the higher geothermal gradient would become lower. Furthermore, in these models the isotherms are distorted, so detailed particle trajectories must to be used in the computation of the uplift rates. Acknowledgements

We thank Messrs. W.K. Chau, D.C. Lee and H. Tsai for their very competent assistance and Miss H.F. Chiu and Mr. H.J. Yang for drafting the figures. The senior author is .indebted to Prof. Bor-ming Jahn and Mr. J. Comichet of the University of Remres for valuable discussion and laboratory tutoring during her visit. Comments from Y.N. Shieh (Purdue) were helpful. This paper

142

C.-Y

has benefitted

from the critical

views of B.M. Jahn (Rennes), and

C.H.

Lo (Princeton)

supported

and thorough

re-

J.G. Liou (Stanford) and

the research

from the National

was

Ho, C.S., 1986. An introduction explanatory

of the Repub-

J. and

Frey,

carbonaceous

Cosmochim.

C.S., Lee, T.Q., Chen,

Tsenwenchi

from the Chipan (C) gneiss body. 87Rb/86Sr and 87Sr/86Sr for muscovite and plagioclase separates were 48.3 k 1.0 and 0.76620 k 0.00008 and 5.5 k 0.1 and 0.71581 k 0.00005, respectively. The RbSr isochron age calculated from the slope of the tie line through these two minerals is 83.4 f 2.3 Ma. This age agrees with the ca. 90 Ma muscovite ages found in bodies F and Y, the whole-rock age for subunits in Ka and F, and the lower intercept age of the U-Pb analysis of zircon for C (Jahn et al., 1986). These new data strengthen the claim that the 90 Ma event was a metamorphic event for the entire region, including Chipan.

building.

2. Thermal

F.A., 1989. Brittle frictional structure

and heat budget.

mountain

ages from coexisting

between

pairs of Rb-Sr

metamorphic

micas.

C.H.,

Chu,

Explanatory Taiwan.

notes

Liou, for

the

area, Taiwan:

marine

W.G.,

facies

from

1983.

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Shakatangchi

and

T.J., 1986. Isotope and exchange

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along

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metamorphism Philos. Trans.

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Laohsichi

area,

Hualien.

10: 11-27. systematics during

in minerals:

biotite

metamorphism.

Tailuko Jahn,

parageneses Gorge,

Central

in Taiwan,

1987.

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Crustal

a post-Palaeozoic

R. Sot. London,

Taiwan:

(Abstr.).

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2: 47-56

of

Quater-

sulfide

ore

of a sphalerite

(in Chinese,

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(Editors),

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in

In: E. JLger and Isotope

Geology.

Berlin, pp. 52-76.

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In: E. JIger

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