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Cenozoic structural history of the Gippsland Basin: Early Oligocene onset for compressional tectonics in SE Australia
Journal Pre-proof Cenozoic structural history of the Gippsland Basin: Early Oligocene onset for compressional tectonics in SE Australia Elizabeth M. Mahon, Malcolm W. Wallace PII:
S0264-8172(20)30026-X
DOI:
https://doi.org/10.1016/j.marpetgeo.2020.104243
Reference:
JMPG 104243
To appear in:
Marine and Petroleum Geology
Received Date: 1 August 2019 Revised Date:
16 December 2019
Accepted Date: 13 January 2020
Please cite this article as: Mahon, E.M., Wallace, M.W., Cenozoic structural history of the Gippsland Basin: Early Oligocene onset for compressional tectonics in SE Australia, Marine and Petroleum Geology (2020), doi: https://doi.org/10.1016/j.marpetgeo.2020.104243. This is a PDF file of an article that has undergone enhancements after acceptance, such as the addition of a cover page and metadata, and formatting for readability, but it is not yet the definitive version of record. This version will undergo additional copyediting, typesetting and review before it is published in its final form, but we are providing this version to give early visibility of the article. Please note that, during the production process, errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. © 2020 Published by Elsevier Ltd.
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Cenozoic structural history of the Gippsland Basin: Early Oligocene onset for compressional tectonics in SE Australia
3 4
Elizabeth M. Mahon*, Malcolm W. Wallace
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School of Earth Sciences, University of Melbourne, Parkville, Vic. 3010, Australia
6 7 8
*Corresponding Author. E-mail address: [email protected] (E. Mahon), [email protected] (M. Wallace)
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ABSTRACT The Gippsland Basin contains some of the largest hydrocarbon accumulations in
12
Australia, and has been in production since the 1920’s. These hydrocarbons are
13
trapped by large growth anticlines offshore, in reservoirs of the Cretaceous to
14
Eocene-aged Latrobe Group. Despite the obvious importance of these growth
15
anticlines, the timing of their formation, and the overall Cenozoic tectonic history of
16
the basin is not well understood.
17
Here, we present a detailed growth strata analysis of the faults and anticlines
18
within the Cenozoic sediments of the Gippsland Basin. This indicates two major
19
phases of tectonism in the basin: 1. Late Cretaceous to Eocene extension, and 2.
20
Oligocene to Holocene compression. Detailed analysis of the extensional phase
21
indicates the development of numerous normal growth faults, which display an
22
overall reduction in the magnitude of extension from the Late Cretaceous to the
23
Eocene, commonly terminating at the top of the Latrobe Group. The shift to
24
compressional tectonism occurred at approximately the Eocene-Oligocene boundary
25
(~34 Ma). A major and widespread episode of compression then occurred, with
26
evidence of growth on anticlines and reverse faults beginning in the early Oligocene.
27
This previously unrecognized early Oligocene event produced significant growth (20
28
to 50% total growth) of the major anticlines which host hydrocarbon accumulations.
29
The early Oligocene event represents the first phase of the compressional tectonic
30
regime that continues to the present day in SE Australia. It appears likely that this
31
Oligocene event affected other basins in SE Australia and probably contributed to 1
32
uplift of the Eastern Highlands. The underlying tectonic cause for this Oligocene
33
compressional regime is enigmatic and may be related to far field tectonic
34
processes.
35
A second pulse of compressional tectonism and anticline growth occurred during
36
the mid-Miocene and is generally more significant in the onshore regions of the
37
basin. The youngest phase of compressional tectonism beginning in the Late
38
Miocene (~10 Ma) is also more intense in onshore regions and is marked by an
39
unconformity that is widespread in SE Australia.
40 41 42
Key words: Gippsland Basin; SE Australia; growth strata; basin inversion; seismic; extension; compression; tectonics
43 44 45 46
1. Introduction The Gippsland Basin has been one of the most prolific hydrocarbon-producing
47
regions in Australian history, containing some of the largest hydrocarbon
48
accumulations in Australia. From the discovery of oil onshore in 1924, to the
49
discovery of giant oil and gas fields offshore in the 1960’s, the Gippsland Basin has
50
contributed extensively to the history of hydrocarbon exploration and production in
51
Australia. A great deal of geological research and exploration was carried out in the
52
basin between the 1960’s and the 1990’s. However, despite this attention, there is
53
relatively little published literature on the basic geology of the basin. The position of
54
the basin on the south-eastern corner of the Australian continent has meant it has
55
been subjected to multiple phases of tectonic movement, including rifting along the
56
southern margin of Australia, rifting on the eastern margin of Australia, and Neogene
57
compressional tectonics (Dickinson et al., 2001). There has been some focus on
58
early basin formation (e.g. Gunn, 1975; Threlfall et al., 1976; Etheridge et al., 1985;
59
Lowry, 1988; Lowry and Longley, 1991), and on young tectonism (e.g. Dickinson et
60
al., 2001, 2002). However, the general Cenozoic tectonic history of the basin has
61
not been well documented.
2
62
Hydrocarbon accumulations in the Gippsland Basin are trapped offshore in broad
63
northeast-southwest trending anticlines. Despite the importance of these structures
64
as traps for hydrocarbon accumulations, the timing of the formation of these
65
anticlines is quite poorly constrained. The timing of anticline growth in the Gippsland
66
Basin has been estimated by various authors to a time period anywhere from the
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Late Cretaceous to the Miocene (e.g. Brown, 1986; Smith, 1988; Maung and
68
Nicholas, 1990; Rahmanian et al., 1990; Duff et al., 1991; Lowry and Longley, 1991;
69
Johnstone et al., 2001; Holford et al., 2011).
70
Sedimentation concurrent with tectonism provides a method to identify the history
71
of structures, and is often referred to as ‘growth strata’ (Childs et al., 2003; Jackson
72
et al., 2017). Measurements of thickness changes of sediment across a structure
73
(fault or fold), in conjunction with chronostratigraphic data (e.g. paleontological
74
information), can provide accurate information regarding the history of growth on the
75
structures (Childs et al., 2003). To date, no studies have quantified tectonic growth
76
episodes on structures in the Gippsland Basin. In this study, we have quantitatively
77
analysed the growth history of structures to determine the timing and intensity of the
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various structural episodes in the Gippsland Basin. We document a hitherto
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unidentified episode of major tectonism during the Oligocene that appears to
80
represent the onset of compressional tectonism in South Eastern Australia.
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2. Geological Setting
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This Gippsland Basin, located on the southeast corner of the Australian continent,
83
occupies a unique position in Australia’s tectonic history. It is part of a series of rift
84
basins which formed along the southern margin of Australia, as Australia and
85
Antarctica rifted apart in the Late Jurassic to Early Cretaceous (Etheridge et al.,
86
1985). The present day Gippsland basin displays a roughly ESE-WNW-oriented
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main depocentre, the Central Deep, flanked by the Northern and Southern Terraces,
88
and the Northern and Southern Platforms (Abele et al., 1988). The Northern Terrace
89
is bounded by the Lake Wellington Fault System to the north, and the Rosedale
90
Fault System to the south. The Southern Terrace is constrained by the Darriman
91
Fault System to the north, and the Foster Fault System to the south (Fig. 1).
92
3
93
94 95
Fig. 1. The main structural features of the Gippsland basin (modified from Abele et
96
al., 1988). Seismic lines used in this study are displayed in red.
97 98 99
The Gippsland Basin initially formed as a northeasterly trending en echelon graben system (Willcox et al., 1992; Power et al., 2001) as part of a pre-rift
100
depression that extended along the southern margin of Australia, linking the Otway,
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Bass and Gippsland Basins (Rahmanian et al., 1990). The basement consists of
102
granites and metamorphics of the Lachlan Fold Belt (Evans, 1986; Willcox et al.,
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1992). Deposition of the Strzelecki Group began during the Early Cretaceous in the
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grabens as an immature, syn-rift, volcanoclastic unit, deposited from braided
105
streams and alluvial fans (Threlfall et al., 1976; Rahmanian et al., 1990; Tosolini et
106
al., 1999). By the end of the Early Cretaceous, rifting shifted to southwest of
107
Tasmania, resulting in uplift and an associated unconformity in the Gippsland Basin,
108
and the compartmentalisation of the Otway, Bass and Gippsland Basins (Rahmanian
109
et al., 1990; Power et al., 2001). The Strzelecki Group underwent complex wrench-
110
style deformation at this time (Threlfall et al., 1976; Willcox et al., 1992). During the
111
Late Cretaceous, Zealandia rifted off the eastern side of southeastern Australia, 4
112
opening the Tasman Sea (Mortimer et al., 2019). An angular unconformity
113
associated with this event separates the Strzelecki Group from the overlying Latrobe
114
Group. This unconformity is particularly distinct on the terraces, but becomes
115
conformable in the Central Deep (Threlfall et al., 1976; Featherstone et al., 1991).
116
The Gippsland Basin then underwent a shift from active rifting, to a post-rift,
117
thermal sag phase, during which normal faulting continued but gradually waned
118
(Evans, 1986; Willcox et al., 1992), creating accommodation space for the
119
siliciclastic Latrobe Group. The Latrobe Group has been subdivided into formations
120
by a number of authors (Bodard et al., 1986; Bernecker and Partridge, 2001). Here,
121
we have used a simplified onshore stratigraphic scheme for the Latrobe Group (Fig.
122
2).
123
South-southeast trending canyons up to 650 m deep (Holdgate et al., 2003)
124
incised into the Central Deep during the Early Eocene, forming the Tuna-Flounder
125
and the Marlin-Turrum formations (James and Evans, 1971; Hocking, 1972). The
126
ages of incision and infill of these features is constrained by palynological data from
127
well penetrations, and indicates that the Tuna canyon incised during the M diversus
128
zone (early Eocene) and the Flounder Formation infilled it during the P asperopolus
129
zone (mid Eocene), after which the Marlin channel incised during the P asperopolus
130
zone, cutting into the southwestern side of the Tuna-Flounder Formation, and
131
partially filled with the Turrum Formation during the N asperus zone (Late Eocene).
132
Due to the transgressive nature of the upper Latrobe Group, the upper boundary
133
of the Group is diachronous, and is oldest offshore and youngest onshore. The top of
134
the Latrobe Group is characterized by an interval of condensed marine sediments
135
known as the Gurnard Formation, a thin unit of glauconitic sandstone, deposited
136
discontinuously across the eastern portion of the basin (James and Evans, 1971).
137
Some authors have interpreted the top of the Latrobe Group as a regional
138
unconformity (Rahmanian et al., 1990; Holdgate et al., 2003; Gibson-Poole et al.,
139
2007; Holford et al., 2011) although we favour a diachronous condensed marine
140
origin for this boundary.
141
The Seaspray Group was deposited over the Latrobe Group, and is dominated by
142
non-tropical shallow and deep-water carbonates (James and Evans, 1971; Gallagher
143
et al., 2001; Wallace et al., 2002), with laterally equivalent brown coals and clastic 5
144
interseam sediments onshore. The basal unit, the Lakes Entrance Formation,
145
comprises the first fully marine sedimentation onshore Gippsland Basin (Holdgate
146
and Gallagher, 2003). It consists of shelfal marine muds and limestones, which
147
experienced extensive submarine canyoning in its upper intervals in the central deep
148
of the basin (James and Evans, 1971; Wallace et al., 2002). Overlying the Lakes
149
Entrance Formation is the Gippsland Limestone, which consists of fossiliferous
150
limestone and marl, and their lateral equivalent coastal plain coals and interseam
151
clastics in the Latrobe Valley (Gallagher and Holdgate, 1996).
152
Structures in the Gippsland Basin reflect the multi-phase tectonic history of the
153
Basin. The basin displays predominantly northwest trending extensional faults in
154
deeper parts of the basin, with northeast trending anticlines and some reverse
155
faulting occurring at shallower depths. These anticlines form traps for the major
156
hydrocarbon reservoirs in the upper Latrobe Group offshore. Timing of the initiation
157
of compressional tectonics in the Gippsland Basin (which resulted in growth of these
158
anticlines) is poorly constrained, and is interpreted as beginning in the Late
159
Cretaceous (Duff et al., 1991), early Eocene (Smith, 1988; Johnstone et al., 2001),
160
early-mid Eocene (Brown, 1986; Lowry and Longley, 1991; Holford et al., 2011), or
161
Late Eocene-Miocene (Maung and Nicholas, 1990; Rahmanian et al., 1990). The
162
basin bounding extensional fault systems have experienced inversion to varying
163
degrees along their lengths (Dickinson et al., 2001). A young phase of
164
compressional tectonism occurred in the late Miocene, resulting in uplift of the
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Strzelecki Ranges and folding of onshore Palaeogene coals (Dickinson et al., 2001;
166
2002).
6
167 168 169
Fig. 2. Major stratigraphic subdivisions of the Late Cretaceous to present sediments
170
in the Gippsland basin (modified from Norvick et al., 2001).
171 172 173
3. Methodology 2D and 3D seismic and well data are available over most of the basin. There are
174
many 3D seismic datasets located offshore, which have been merged into a
175
‘Megacube’ seismic volume. This merged 3D seismic was used to undertake seismic
176
interpretation of faults and horizons. The volume is SEG reverse polarity 7
177
(otherwise referred to as ‘European’ polarity), full stack, and approximately zero-
178
phase. Interpretation of 2D seismic was undertaken on the nearshore and onshore
179
areas (where 3D data was unavailable). Data was obtained from the Geological
180
Survey of Victoria, Australia.
181
Well control in the Gippsland Basin is generally good, with over 400 exploration
182
wells, and many more development wells available. Well logs include gamma ray,
183
sonic, neutron porosity, and neutron density. Biostratigraphic data for the
184
Seaspray Group is derived from planktonic foraminiferal analysis. A zonation
185
scheme for offshore wells was first developed by Taylor (1965a, b, 1966) and later
186
refined by him (e.g. Taylor, 1975, 1977, 1979). This zonation scheme consists of a
187
series of lettered “zonules” (Fig. 2) (discussed in detail in Abele et al., 1988) which
188
can be correlated to international planktonic foraminiferal zonation schemes
189
(Gradstein et al., 2012). Onshore, various biostratigraphic schemes have been used
190
(mainly Carter zones – Carter, 1958a, b) and these can also be correlated to the
191
international scheme of Gradstein et al (2012). Foraminiferal data is derived from a
192
series of unpublished open file biostratigraphic reports that are available for many of
193
the onshore and offshore wells of the Gippsland Basin (largely authored by C. Abele
194
in the onshore and D.J. Taylor in the offshore). The onshore wells Wurruk Wurruk-1
195
and Boole Poole 1 were the subject of a detailed foraminiferal/biostratigraphic study
196
(Holdgate and Gallagher, 1997) and these cored wells can be correlated to nearby
197
wells with electric logs and seismic data.
198
The chronostratigraphic framework for the Latrobe Group is largely derived
199
from palynological spore-pollen and dinoflagellate zonation schemes (James and
200
Evans, 1971; Partridge, 1971; Stover and Evans, 1973; Stover and Partridge,
201
1973; Partridge 1976; Partridge, 1999; Warne et al., 2003; Partridge, 2006) in
202
combination with numerous unpublished palynological reports that are available
203
for most petroleum wells from the Gippsland Basin. These biostratigraphic
204
zonation schemes have here been updated to the Gradstein 2012 time-scale
205
(Gradstein et al., 2012; Korasidis et al., 2018, 2019). Specific wells of importance
206
in this study were Barracouta 3 (Stover and Partridge, 1971), Veilfin 1 (Hannah and
207
Macphail, 1985) and Teraglin 1 (Macphail, 1983).
8
208
Seismic horizons were interpreted across each structure, as closely spaced as
209
data allowed. Regional correlations tied to biostratigraphic data were correlated to
210
each structure and used as biostratigraphic datums for age determination on each
211
structure. The thicknesses (in two-way-time) of the syn-tectonic sedimentary
212
packages were measured at two locations across each structure. For growth
213
anticlines, the crest and hinge locations were used, with preference given to a hinge
214
location that was not separated from the crest by faulting. Intervals were measured
215
vertically, and intervals that have been eroded at the crest of the structure were not
216
included. For growth faults, the footwall and hanging wall were measured as close to
217
the fault as possible. In total, ten different structures were quantitatively assessed for
218
structural growth; the Mackerel, Fortescue, Salmon, and Barracouta extensional fault
219
blocks, and the Dolphin, Barracouta, Golden Beach, Darriman and Baragwanath
220
anticlines, and the Baragwanath fault. The specific structures studied were selected
221
based on their location in the basin, with the aim of gaining a representative spread
222
of geographic areas and structure types. Faults located in the Central Deep of the
223
basin were targeted for analysis. Measurements were taken from the centre of the
224
fault traces, in order to minimise any fault-tip effects which may skew the fault growth
225
analyses. Normal faults that have been inverted were also avoided for growth strata
226
analysis.
227
Thickness measurements of sediment packages across each structure were used
228
to determine the Expansion Index (EI). The EI is a ratio of the thickness of growth
229
sediments between the upthrown (or on-structure) and downthrown (or off-structure)
230
locations (e.g. anticline crest and hinge respectively) (Thorsen, 1963). An EI of 1
231
indicates no growth, while an EI of >1 indicates structural movement and growth
232
sedimentation (Jackson et al., 2017). (1)
233
Expansion Index = a / b (Thorsen, 1963)
234 235 236 237 238
Where: a = twt of individual downthrown package
239
b = twt of individual upthrown package
240 241
(twt = two-way-time)
9
242 243
The EI displays the expansion, or growth of individual sediment intervals.
244
However, it is difficult to assess the relative amount of structural growth from EI data.
245
This is because different thickness (twt) intervals are used for each calculation based
246
on which horizons can be correlated accurately. For example, a relatively thin unit
247
may display a very large expansion index and appear as a significant episode of
248
growth on the plot. However, because the unit is relatively thin, it will represent a
249
very small proportion of total growth on the structure and may be unrepresentative in
250
terms of the overall growth history. Hence we have calculated another function
251
which we have called the Growth % (Fig. 3). The Growth % provides the proportion
252
of total growth on the structure for each interval and this function appears to provide
253
a more quantitative and representative picture of the relative growth on the structure
254
over time. The equation used is as follows. (2)
255
Growth % = ((a – b) / (A – B)) *100
256 257 258
Where:
259
a = twt of individual downthrown package
260
b = twt of individual upthrown package
261
A = twt of total downthrown section
262
B = twt of total upthrown section
263 264
(twt = two-way-time)
265 266
Each growth analysis diagram displays the measured sediment packages and biostratigraphic datums.
267 268
10
269
270 271 272
Fig. 3. Diagram illustrating the variables used in the calculation of the Growth % equation (Equation 2).
273 274 275
4. Uncertainties and Limitations Studies of structural growth on anticlines and faults have used either sediment
276
thickness (e.g. Thorsen, 1963) or two-way-time on seismic profiles (e.g. Mansfield
277
and Cartwright, 1996; Jackson et al., 2017), depending on the data available
278
(seismic, outcrop or wells) and the purpose of the study. Several authors have noted
279
that fault growth plots for faults commonly appear similar whether presented in depth
280
or two-way time, especially if sonic velocity varies gradually with depth and there are
281
no significant lateral velocity variations (Baudon and Cartwright, 2008; Omosanya et
282
al., 2015).
283
In the Gippsland Basin, sonic velocities in the Seaspray Group generally increase
284
gradually with depth. Lateral variations can be present and are related to submarine
285
canyons (Wallace et al., 2002). Using typical velocity gradients for the Seaspray
286
Group (Wallace et al., 2002), we estimate that on the structures with the thickest
287
growth, Growth % plots would underestimate the oldest growth by around 15%.
288
This would mean that our growth plots slightly underestimate the significance of the
289
oldest (Oligocene) growth in the Seaspray Group. This would not significantly affect 11
290
the timing estimates for structural growth presented in this study.
291
in velocity due to the presence of submarine canyons are unlikely to affect our
292
structural growth estimates because such large-scale canyons are visible on seismic
293
images and we have avoided measuring across them. A potential source of lateral
294
velocity variation that might affect growth calculations would be the presence of
295
different lithologies on structural highs (e.g. higher carbonate contents on highs).
296
However, there are no completely off-structure wells to provide a lithologic
297
comparison. Additionally, lateral facies change of this nature would be expected to
298
affect most of the Seaspray Group section and changes in growth rates would still be
299
visible on growth analysis plots. Velocity gradients in the Latrobe Group tend to be
300
lower than those in the Seaspray Group, with consequently lower errors.
301
Lateral variations
Another source of error in estimates of growth on structures is the effect of
302
differential compaction (Mansfield and Cartwright, 1996). Sediments on structural
303
highs are subjected to lower depths of burial and hence less compaction than off-
304
structure sediments. This effect is somewhat related to sonic velocity (as sonic
305
velocity is largely controlled by compaction and porosity), and has the same
306
outcome, resulting in underestimation of the growth history of more deeply buried
307
strata (i.e. Oligocene growth will be underestimated in the Seaspray Group).
308
Interstratal variations in lithology and compaction tend to be cancelled out by the
309
analysis of several different geographic regions and structures.
310
Differential compaction has occurred in the Latrobe Group due to the presence of
311
lateral facies changes. This is particularly evident in the upper interval of the Group,
312
as a result of sand-rich barrier systems. This form of differential compaction has
313
been taken into account in this study, as the sandy barrier systems of the Latrobe
314
Group can be easily recognised on seismic profiles (e.g. Fig. 9 Barracouta Fault,
315
Fig.11 Dolphin Anticline).
316
A source of uncertainty in the relative age of structural growth is the spacing of
317
interpreted seismic horizons and age datums. In the seismic data from the deeper
318
water Seaspray Group, it is commonly difficult to interpret seismic reflectors over
319
large distances due to many small (<50 m deep) erosional features that are related
320
to small-scale submarine canyon systems. Widely-spaced seismic horizons will
321
result in less detailed age determinations for specific growth events.
322 12
323 324
5. Results Analysis of growth across a range of structures was undertaken in the Gippsland
325
Basin. These structures fall into two clear groups: those that occur within the Latrobe
326
Group and those that occur within Seaspray Group. These structures are clearly
327
evident on seismic data as large anticlines and faults (Figs. 4, 5).
328 329
Fig. 4. Top Latrobe Group two-way-time-structure map over the 3D Megacube area
330
(offshore Gippsland Basin). Faults analysedin this study are shown in black. The
331
Dolphin, Golden Beach and Barracouta anticlines (analysed here) are also shown.
332
The white line (Z-Z’) is shown as a seismic section on Fig. 5.
333
13
334 335
Fig. 5. Megacube arbitrary line Z-Z’ (located on figure 4). Latrobe Group faults
336
analysed are depicted in a hard black line. Grey dashed lines indicate bends in
337
seismic profile. See Fig. 4 for line location.
338 339
5.1 Latrobe Group Structures
340
Virtually all faults within the Latrobe Group have growth strata which indicate a
341
normal sense of movement. Normal growth faults are evident on seismic profiles by
342
a thickening of sedimentary packages into the hanging wall of the fault. These
343
normal growth faults are more common offshore, with faults generally terminating at
344
or close to the Top Latrobe Group reflector.
345
The Mackerel fault block is a northwest trending block, which dips to the
346
southwest. It is bound by northwest trending normal faults, which both dip to the
347
northeast. The fault block contains three well penetrations - Halibut 1, Trumpeter 1
348
and Mackerel 3. The growth strata on the southern bounding fault of this fault block
349
were analysed (Fig. 6). At this location the Top Latrobe Group horizon is affected by
14
350
marine erosion on the northern side of the fault block. This is associated with post-
351
Latrobe Group erosion.
352
The Expansion Index plot shows multiple intervals of increased growth, with a
353
maximum EI of 1.5, in the base F longus. The Growth % plot for the Mackerel fault
354
block shows four distinct phases of growth, with an overall reduction in magnitude of
355
growth over time. A feature not readily apparent on the expansion index plot is a
356
large amount of growth at the base of the interval analysed (Late Cretaceous – T
357
lilliei time). On this structure, 39% of the total growth occurred during the mid-Late
358
Cretaceous (T lilliei), 45 % during the late Late Cretaceous (F longus), while only
359
17% occurred during the late Palaeocene (Upper L balmei). The fault terminates at
360
the Top Latrobe Group horizon, when growth was less than 5%.
361
362 363
Fig. 6. 3D Megacube inline 4253 with biostratigraphic datums and showing Mackerel
364
fault block growth analysis. See Fig. 1 for line location.
15
365
The Fortescue fault block is a west-northwest trending fault block, which dips to
366
the south-southwest. It is bound by west-northwest trending normal faults, which
367
both dip to the north-northeast. It contains the wells Fortescue 1, Fortescue 3, and
368
West Halibut 1. The southern fault of this fault block was analysed (Fig. 7).
369
The Expansion Index shows three phases of increased growth. The Growth % plot
370
displays correlative phases of increased total growth to the EI, with the largest
371
growth occurring during the Late Cretaceous (Lower F longus). On this structure,
372
42% of the total growth occurred during the Late Cretaceous (Lower F longus), 21%
373
occurred during the early Palaeocene (Lower L balmei), another 21% occurred
374
during the late Palaeocene (Upper L balmei), and 16% occurred during the middle
375
Eocene (P asperopolus). This again shows a pattern of reduction in growth over
376
time, terminating at the Top Latrobe Group horizon with the cessation of normal
377
faulting.
378 379
Fig. 7. Megacube inline 3807 with biostratigraphic datums and showing Fortescue
380
fault block growth analysis. See Fig.1 for line location.
16
381
The Salmon fault block trends northwest, and dips to the southwest. It is bound by
382
two northwest dipping normal faults, and contains the wells Salmon 1 and Vielfin 1.
383
The southern fault of this fault block was analysed (Fig. 8). The Expansion Index plot
384
has a variable character, with every individual interval displaying growth except the
385
uppermost Latrobe Group (N asperus), which has an EI = 1 indicating no growth.
386
The Growth % plot shows a slightly variable growth character, with growth
387
gradually waning with time. On the Salmon block, 30% of the total growth occurred in
388
the late Palaeocene (Upper L balmei), 46% in the early Eocene (M diversus), 15% in
389
the early-mid Eocene (P asperopolus), and 9% in the late Eocene (Middle N
390
asperus). Normal faulting appears to have ceased at the Top Latrobe Group (middle
391
Eocene - P asperopolus time), with sediments infilling accommodation space (and so
392
showing growth) until just after this time, during the late Eocene (N asperus).
393
394 395
Fig. 8. Megacube inline 2989 with age datums and showing Salmon fault block
396
growth analysis. See Fig.1 for line location.
397
The Barracouta fault block trends west-northwest, and is located on the southern
398
side of the Barracouta anticline. It is bound by a normal fault to the south, and by a
399
(currently) reverse fault to the north. The southern fault was analysed (Fig. 9). The
400
Expansion Index plot has a variable character, though there appears to be two 17
401
phases of increased growth; during the middle Palaeocene (L balmei time), and the
402
mid Eocene (P asperopolus to N asperus time).
403
The Growth % plot for the Barracouta Fault block again shows growth gradually
404
reducing with time. The majority of the growth (73%) occurs in the late Palaeocene
405
(L balmei), and 31% of the total growth occurs during the mid-Eocene (P
406
asperopolus). By late Eocene time (middle N asperus) growth transitions from 18%
407
to negative (i.e. apparent compression). The apparent compression is likely due to a
408
facies change within the Latrobe Group.
409
410 411
Fig. 9. Megacube inline 2057 with biostratigraphic datums and showing Barracouta
412
fault block growth analysis. See Fig. 1 for line location.
413 414
5.2 Seaspray Group Structures
415
Growth anticlines and reverse faults dominate the structures of the Seaspray
416
Group, both in the onshore and offshore regions. On seismic data, thickening of
417
sedimentary packages is evident adjacent to anticlinal structures and thinning over
418
the crest of the anticline. The same is apparent for reverse faults. In contrast to the 18
419
underlying Latrobe Group, there is no evidence of normal faulting within the
420
Seaspray Group.
421
The Barracouta anticline (Fig. 10) is one of the largest structures in the offshore
422
Gippsland Basin. It is a northeast trending structural high, has numerous well
423
penetrations, and contains significant hydrocarbon reserves in the upper Latrobe
424
Group. Basal Seaspray Group sediments which onlap the structure fall within the P
425
tuberculatus palynological zone.
426
The Expansion Index plot for the Barracouta anticline displays a negative EI value
427
at the uppermost Latrobe Group interval, indicating thickening of sediments onto the
428
crest (caused by the presence of sandy barrier facies on the crest of the anticline).
429
This indicates anticline growth likely had not begun yet. Immediately above the
430
Latrobe Group, in the Oligocene to early Miocene, EI values increase abruptly up to
431
9 indicating a large amount of growth. EI values subsequently remain relatively low
432
to the top of the interval analysed, in the mid Miocene (just above Taylor zone C).
433
Above this, the crest of the structure has experienced erosion, evident by truncated
434
reflectors. While growth rate cannot be quantified due to this erosion, it indicates the
435
Barracouta anticline continued growing.
436
The Growth % plot for the Barracouta anticline shows a similar pattern. Growth is
437
negative in the uppermost Latrobe Group, due to pre-anticline facies distribution in
438
the Latrobe Group. Beginning quite abruptly above the middle N asperus-Top
439
Latrobe Group reflector is a significant pulse of growth. Here, 64% of the total
440
growth of the Barracouta anticline occurred in the Oligocene-early Miocene - the
441
majority of which occurred in the Oligocene. Moderate growth occurred during the
442
mid-Miocene, remaining below 20%. Growth was reduced significantly in the late
443
Miocene, remaining below 5%. Subsequent Late Miocene-early Pliocene growth is
444
inferred by erosion of the anticline crest after this time.
445
19
446
447 448
Fig. 10. Megacube inline 2079 with key horizons, showing Barracouta anticline
449
growth analysis. See Fig.1 for line location.
450
The Dolphin anticline (Fig. 11) trends northeast, and is located south of the
451
Barracouta anticline. Basal Seaspray Group sediments which onlap the structure are
452
interpreted as Taylor zone J1. The Expansion Index plot for the Dolphin anticline
453
displays growth in the upper Latrobe Group (middle N asperus, Late Eocene).
454
However, this apparent structural growth is due to a lateral facies change within the
455
Latrobe Group, rather than structural growth (a middle N. asperus sandy barrier is
456
present in the syncline). The EI remains above 1 until the mid Miocene (Taylor zone
457
C). After this time it drops below 1, indicating no growth of the structure. Above this,
458
the Dolphin Anticline has experienced erosion at the crest, evident by an angular
459
unconformity at or close to the seafloor. This erosion is indicative of anticline growth,
460
though it can’t be confidently quantified.
461
The Growth % plot for the Dolphin anticline indicates 48% of the total growth
462
occurred during the Oligocene to Early Miocene (between the N asperus and Taylor
463
zone G times). Growth on the structure gradually reduced during the Miocene, 20
464
although 37% of the total growth occurred during this time (Taylor zone G to Taylor
465
zone C). Above this, growth becomes negative. This is likely reflecting lateral
466
sedimentation changes, and not structural movement. Above this, an erosional
467
surface is evident, indicating growth of the anticline again.
468
469 470
Fig. 11. Megacube arbitrary line with biostratigraphic datums, showing Dolphin
471
anticline growth analysis. See Fig.1 for line location.
472
The Golden Beach anticline (Fig. 12) is located close to the present-day coastline,
473
and trends northeast. It has multiple well penetrations, including Golden Beach 1.
474
Basal Seaspray Group sediments are dated at Taylor zone K. The Expansion Index
475
plot for the Golden Beach anticline displays EI values of 1 in the upper Latrobe
476
Group, indicating no anticlinal growth. Above this, the EI is highly variable in value,
477
ranging from just above 1, up to almost 6. The largest EI occurs in the mid Miocene
478
(just above Taylor zone G). EI does not drop below 1, indicating growth to the top of
479
the interval analysed, in the mid Miocene. Above this, erosion is evident by an 21
480
angular unconformity just below the sea floor, again, indicating continued anticline
481
growth.
482
The Growth % plot shows almost no growth in the upper Latrobe Group, then a
483
sudden onset of growth immediately above the Top Latrobe Group reflector, in the
484
basal Seaspray Group. 59% of the total growth occurs in the Oligocene-early
485
Miocene, the majority of which occurs in the Oligocene. The Growth % is variable
486
after this time, with 26% occurring in the early-mid Miocene (Taylor zone G to Taylor
487
zone C). Growth % remains positive to the top of the interval analysed.
488
489 490
Fig. 12. 2D seismic line GGS185AE-02 with biostratigraphic datums and showing
491
Golden Beach anticline growth analysis. See Fig. 1 for line location.
492
The Darriman Anticline (Fig. 13) is located in the southern area of the onshore
493
Gippsland Basin. It is associated with one of the main bounding faults of the
494
southern margin of the basin, the Darriman Fault System. Measurements were taken
495
on the northern side of the anticline. Expansion Indices for the Darriman Anticline are
496
variable, although they do not display the very high indices of offshore anticlines. 22
497
Except for a short interval in the mid Miocene, EI values remain above 1, indicating
498
continued growth of the anticline. Indices are largest immediately above the Latrobe
499
Group reflector (approximately Eocene-Oligocene boundary), and during the mid
500
Miocene. The present day land surface is an angular unconformity. This indicates
501
continued growth on the structure which post-dates the youngest strata in the section
502
(~10 Ma).
503
The Growth % plot shows minor growth in the upper Latrobe Group, similar to
504
Dolphin 1. This is again interpreted as a result of lateral facies changes within the
505
Group. Overall, the Growth % reflects a similar pattern to EI, displaying a period of
506
increased growth immediately above the Latrobe Group reflector, in the Oligocene
507
basal Seaspray Group, and again in the mid Miocene. Growth in the Oligocene to
508
early Miocene accounts for 37% of the total growth of the anticline, while 33% of
509
growth occurred in the mid Miocene (Taylor zone G to Taylor zone C), and 21 %
510
occurred in the late mid Miocene.
511
512 513
Fig. 13. 2D seismic line GCR87B-101 and GCR87B-101a with biostratigraphic
514
datums and showing Darriman anticline growth analysis. See fig. 1 for line location. 23
515
The Baragwanath anticline is a large anticline trending roughly east-west across
516
the onshore section of the Gippsland Basin, and has many well penetrations (Fig.
517
14). The Expansion Index plot for the Baragwanath Anticline shows EI’s consistently
518
>1, which range from 1.5 to 3.5. The interval with the largest EI occurs in the
519
Oligocene (EI =3.5). Above this, sediments are truncated by surface erosion at the
520
crest of the structure, indicating continued structural growth.
521
The Growth % plot for the Baragwanath Anticline shows a small (EI =2) amount of
522
apparent growth in the upper Latrobe Group (again, due to a stratigraphic feature- an
523
unconformity over the Latrobe Group). Growth % increases above this, and although
524
not with the distinct sudden onset characteristic of the offshore structures, the time
525
of maximum growth – 41% occurs during the early Oligocene. On this structure,
526
13% of growth occurs during the early Miocene, and 27% during the mid Miocene.
527
528 529
Fig. 14. 2D seismic line GHG-85a-4 biostratigraphic datums and showing
530
Baragwanath anticline growth analysis. See Fig. 1 for line location.
531
The Baragwanath Anticline has two similar-trending reverse faults along its
532
southern side, which roughly parallel the trend of the anticline. The easternmost of
533
these two faults was analysed for growth rates (Fig. 15). The Expansion Index plot
534
for the Baragwanath Fault shows only minimal growth, with EI values only slightly
24
535
above 1. The interval with the largest EI is immediately above the Top Latrobe Group
536
reflector (in the early Oligocene), where EI=1.2.
537
The Growth % plot shows negative to low growth in the upper Latrobe Group
538
during the early Oligocene (Upper N. asperus and older), then sudden, significant
539
growth during approximately the early Oligocene, gradually reducing to almost zero
540
by the end Oligocene. Oligocene growth accounts for 60 % of the total growth of the
541
structure. In the early Miocene growth increased suddenly again, and with the
542
exception of a short period of no growth in the mid Miocene, growth continued.
543
Miocene growth contributed 44 % to the total growth.
544
545 546
Fig. 15. 2D Seismic line GHG85a-3 with biostratigraphic datums, and showing
547
Baragwanath Fault growth analysis. See Fig. 1 for line location.
548 549 550 551
6. Discussion Growth % plots for the Gippsland Basin in the Late Cretaceous and Cenozoic display two major phases of tectonic activity. The Latrobe Group is exclusively 25
552
dominated by normal growth faulting, indicating an extensional tectonic regime.
553
Growth across these faults is evident from the oldest intervals analysed (Late
554
Cretaceous – T lilliei), to the youngest Latrobe Group intervals analysed (Late
555
Eocene – end Lower N asperus). In contrast, the Seaspray Group is dominated by
556
reverse growth faults and growth anticlines, indicating a compressional tectonic
557
regime. Growth on these compressional structures appears to begin at
558
approximately the Eocene-Oligocene boundary (~34 Ma), and continues to the
559
youngest intervals analysed (late Miocene – Taylor zone C). Thus, the transition
560
from extensional to compressional regimes occurs during the Latest Eocene to early
561
Oligocene (~34 Ma). Fig. 16 shows a summary of the growth history of all structures
562
analysed in this study in the Gippsland Basin.
563
564 565
Fig. 16. Plot of structural growth in the Gippsland Basin from the Late Cretaceous to
566
the late Miocene, based on growth % plots from each of the structures analysed.
567
Structures appear to undergo a shift from dominantly extensional to dominantly
568
compressional at around the Eocene-Oligocene boundary ~34 Ma. C, E2, G, H1
569
from Taylor foraminiferal zonation scheme. 26
570 571 572 573
6.1 Extensional Structures Extensional structures in the Gippsland Basin are constrained to the Latrobe
574
Group (and older) sediments. Normal faults in the Latrobe Group show clear
575
thickening of sediments into the hanging wall of these faults. In general, structural
576
growth reduces in magnitude over time, ceasing in the mid to late Eocene (Fig. 16).
577
The Growth % plots for these faults have a generally irregular, ‘pulsed’ appearance.
578
This pulsed or episodic growth character may be due to intermittent fault movement
579
related to the building and release of strain on the fault (Ren et al., 2013).
580
Alternatively, the pulsed appearance might be due to accommodation of strain
581
shifting to other faults in the region.
582
Episodic fault displacement created accommodation space for Latrobe Group
583
sediments in stages, resulting in alternating periods of growth and no growth of
584
sediments across the fault. This episodic fault behaviour has been documented on
585
faults in other basins (Wallace, 1987; Nicol et al., 2005; McClymont et al., 2009;
586
Jackson and Rotevatn, 2013). There appears to be no uniformity in the timing of
587
displacement on the normal faults, nor any relationship to location in the basin.
588
Displacement events on extensional faults appear to have occurred at different times
589
in different parts of the basin. The only observable trend in normal fault growth
590
across the basin is a general waning during Latrobe Group deposition.
591
The data presented here show that extensional faults terminate at or very close to
592
the Top Latrobe Group reflector. However, the Top Latrobe Group is a diachronous
593
horizon, being oldest in the Central Deep to the east and youngest onshore to the
594
west. Given the shift from an extensional to a compressional regime appears to be a
595
regional event, it is reasonable to assume that the youngest sediments showing
596
offset by normal faulting are indicative of when extensional faulting ceased. Thus
597
extensional tectonics in the Gippsland Basin appears to have ended in the latest
598
Eocene.
599
27
600
6.2 Compressional Structures
601
Analysis of growth strata from this study indicate that the tectonic regime in the
602
Gippsland Basin changed from extensional to compressional during latest Eocene to
603
earliest Oligocene time (~34 Ma). The major outcome of this compression was the
604
formation of broad, roughly northeast-southwest trending anticlines in the Central
605
Deep, which today host major hydrocarbon accumulations in the basin (Dickinson et
606
al., 2001). This compressional regime continued into the Neogene, and in addition to
607
anticline formation, reactivation and inversion of previously extensional faults within
608
the Latrobe Group occurred. The Baragwanath Fault (a reverse fault, Fig. 15)
609
displays episodic growth similar to normal faults in the Latrobe Group, as opposed to
610
the more continuous growth behaviour evident on the anticlines.
611
The anticlines studied here generally display two major pulses of growth. The first
612
began at approximately the Eocene-Oligocene boundary (~34 Ma) and continued to
613
the early Miocene (~20 Ma). Where finer scale correlation across structures allows
614
for a more precise timing (e.g. Darriman Anticline, Fig. 13), a large amount of this
615
growth is observed to occur in the early Oligocene. During the Oligocene to early
616
Miocene, anticlinal growth occurred on both onshore and offshore structures, with
617
the magnitude and proportion of growth varying between structures. A second phase
618
of anticlinal growth occurred in the mid-Miocene, and appears to have largely
619
affected onshore anticlines. Offshore structures, however, did not experience this
620
second pulse of increased growth so strongly (or at all in some cases), and instead
621
appear to have remained in a low growth phase from the early Miocene (~20 Ma),
622
until at least the Miocene-Pliocene boundary. At this time erosion is evident,
623
indicating the anticlines began growing again.
624
Concurrent with early anticline growth was deposition of the Seaspray Group. The
625
lower Seaspray Group shows onlap onto the major anticlines and thinning of upper
626
intervals over anticline crests (e.g. Fig. 10, Barracouta anticline), clearly indicating
627
anticlines were growing at the same time deposition was occurring. Despite these
628
compressional events, the basin was still subsiding. Sediments of the Seaspray
629
Group were deposited in deep marine environments (in the offshore part of the
630
basin), characterised by marine calcareous muds and limestones (Holdgate and
631
Gallagher, 2003). The offshore Seaspray Group is characterized by abundant 28
632
submarine canyons (Wallace et al., 2002) indicating an outer shelf and slope setting.
633
A common theme evident on Growth % charts for each structure is a very large and
634
sudden onset of growth in the early Oligocene. This first phase of compression,
635
occurring from the early Oligocene to early Miocene, displays the most growth
636
across both onshore and offshore structures. Brown (1986) suggested that the
637
Dolphin anticline likely had relief in the early stages of post-Latrobe Group
638
sedimentation, due to thinning of sediments toward the anticline. Dickinson et al.,
639
(2001) also noted the onlap and thinning of Oligocene sediments across some of the
640
large offshore anticlines, indicating structural growth at that time. After deposition of
641
the Latrobe Group, there was a period of low sedimentation evident from
642
palynological data showing condensed intervals (and localised, brief unconformities),
643
and deposition of the glauconitic Gurnard Formation. The sudden onset of the first
644
early Oligocene compressional phase may in part reflect reduced sedimentation at
645
the top Latrobe Group-lower Seaspray Group boundary. However, there is no
646
evidence of onlap or thinning of Latrobe Group sediments over the anticlines. In
647
addition, faulting remains extensional until the late Eocene, which suggests that
648
compression and subsequent anticline growth did not occur before this.
649
Previous interpretations of the major hydrocarbon-bearing anticlines of the
650
Gippsland Basin beginning to develop in the early to mid-Eocene appear to be based
651
on the interpretation of large, incised canyons (i.e. the Marlin and Tuna canyons) in
652
the Latrobe Group as resulting from fluvial incision (e.g. Hocking, 1972; Brown
653
1986). This interpretation of deeply incised fluvial canyons implies significant uplift of
654
the basin and hence possible compression during the mid-Eocene. This
655
interpretation first appears in some earlier papers on the Gippsland Basin (Hocking,
656
1972; Threlfall, 1976) at a time when seismic and well data were limited in the
657
Gippsland Basin. There is no evidence to suggest that the Marlin-Turrum and Tuna-
658
Flounder canyons are the result of fluvial incision, and are perhaps of submarine
659
incision origin (as are the abundant canyons in the overlying Seaspray Group). If
660
these canyons were of submarine origin, they are likely unrelated to tectonic uplift.
661
Importantly, there is no evidence for regional unconformities of mid Eocene age
662
within the Latrobe Group. Regardless of the origin of the mid-Eocene canyon
663
systems, there is also no evidence for anticline growth during Latrobe Group time.
29
664
Furthermore, the canyon fill is cut by normal faults (showing extension occurring
665
after infilling) and is subsequently deformed by folding.
666
In the offshore Gippsland Basin, the Oligocene compressional event essentially
667
ceased in the early Miocene, with the Dolphin, Barracouta and Golden Beach
668
anticlines experiencing significantly reduced growth. This low growth of structures
669
persisted to the youngest sediments analysed, in the late Miocene. It is assumed to
670
continue to at least the Miocene-Pliocene boundary, as on seismic lines, structural
671
highs appear peneplained (e.g. Dolphin anticline – Fig. 11). Where seismic
672
resolution allows, this appears as an angular unconformity overlain with horizontal
673
strata. This unconformity coincides approximately with the Miocene-Pliocene
674
boundary, and is particularly evident on the Golden Beach structure (Figs. 12,17).
675
Dickinson et al., (2001, 2002) discussed the Miocene-Pliocene unconformity in
676
detail, observing it in the Murray, Otway, Torquay and Port Phillip Basins, as well as
677
the Gippsland Basin. They also documented erosion of anticlines from shallow
678
seismic data.
679
In the onshore Gippsland Basin, structures underwent a second phase of growth,
680
beginning in the middle Miocene and lasting until the youngest sediments analysed,
681
in the late Miocene. This second phase of compression is not seen in offshore
682
structures. This pattern of more intense structural development onshore continues
683
into the younger tectonic regime. The Late Miocene-Pliocene episode of tectonics is
684
also more intense in onshore settings than in the offshore. In the onshore Latrobe
685
Valley, hundreds of meters of uplift and erosion occurred, with significant uplift of the
686
Strzelecki Ranges (Dickinson et al., 2001, 2002). While the Late Miocene-Pliocene
687
tectonic episode did affect the offshore, it was significantly less intense than in the
688
onshore.
689
30
690 691
Fig. 17. Interpretation of 2D seismic line GGSI85AE-02, which crosses the Golden
692
Beach structure at the northeastern end of the seismic line. Note the thinning of the
693
Oligocene-Miocene interval over the anticline.
694 695 696
6.3 Cenozoic tectonics in SE Australia Australia is commonly regarded as having an insignificant record of Cenozoic
697
uplift and tectonics, with ancient landscapes dominating the geomorphology (e.g.
698
Pain et al., 2012). Some authors have suggested Mesozoic ages for many Australian
699
landscape features like the Southeast Highlands (e.g. Vandenberg, 2010; Webb,
700
2017), while others have suggested much younger tectonic events have been
701
important in SE Australia (Dickinson et al., 2002; Holdgate et al. 2008). The origin of
702
the Southeast Highlands is historically a contentious area of research, with authors
703
proposing old origins for the uplift (uplift in the Mesozoic, e.g. Vandenberg, 2010),
704
very young origins (uplift in the Plio-Pleistocene, e.g. Andrews, 1910) or continuous 31
705
uplift since the Mesozoic (e.g. Wellman, 1979). However, some researchers have
706
argued for a largely post-Eocene origin for this uplift (e.g. Browne, 1969; Holdgate et
707
al., 2008). Recent research undertaken by Greenwood et al., (2017) on vegetation
708
type of the Highlands through geologic time is consistent with a significant episode of
709
post-Eocene uplift affected the SE Highlands. It has been suggested that up to 50%
710
of the present-day topographic relief in the Southeast Highlands formed in the last 10
711
Ma (Braun et al., 2009). Given that the younger tectonic events in the Gippsland
712
Basin (mid-Miocene and Late Miocene-Pliocene) appear to be more intense in
713
onshore positions, it appears likely that post-Eocene compressional tectonics
714
(including the early Oligocene event documented here) and uplift have affected the
715
SE Highlands inshore from the Gippsland Basin.
716
The Oligocene compressional event documented here appears to be a significant
717
event in the Gippsland Basin and almost certainly affected other areas in SE
718
Australia. Evidence for this compressional tectonism has been documented in
719
surrounding basins. The Bass Basin, located immediately southwest of the
720
Gippsland Basin, displays a series of hydrocarbon-bearing anticlines which formed
721
during the Oligocene-Miocene as a result of transpressional inversion (Cummings et
722
al., 2004; Leech et al., 2008). West of the Bass Basin, the Torquay Sub basin of the
723
Otway Basin displays anticlines which began growing in the Oligocene and
724
underwent a second phase of inversion in the Miocene (Young et al., 1991). An
725
angular unconformity is also evident in the onshore Torquay Sub basin, in the
726
Anglesea coal mine, which has been dated palynologically at ~39-40 Ma (Holdgate
727
et al., 2001). This unconformity is believed to be related to significant late Eocene
728
uplift, associated with the Otway Ranges (Holdgate et al., 2001).
729
There is some uncertainty surrounding the cause of the initiation of compressional
730
tectonism in SE Australia. Previous interpretations which have placed the timing of
731
compression earlier (early-mid Eocene) have linked it with the onset of fast sea floor
732
spreading in the Tasman Sea (e.g. Lowry and Longley, 1991; Norvick et al., 2001;
733
Holford et al., 2011; Holford et al., 2014). However, data presented here shows
734
compression likely initiated approximately 10-15 Ma later, at (or close to) the
735
Eocene-Oligocene boundary. At this time, there were a number of smaller tectonic
736
events which affected the continental margins of Australia. These include:
737
development of the Solomon Sea and Caroline Plate on the northeast margin of the 32
738
Australian Plate (Honza et al., 1987; Smith, 1990), oceanic spreading at the South
739
Tasman and Emerald Basins southwest of NZ (Lebrun et al., 2003), and the final
740
separation of Australia and Antarctica at the South Tasman Rise, directly south of
741
the Gippsland Basin (Hill and Exon, 2004; Scher et al., 2015). There is also evidence
742
for a significant unconformity and reverse fault movement on the Lord Howe Rise at
743
around the Eocene-Oligocene boundary (Sutherland et al., 2010). Identification of
744
the exact driver for the initiation of compression in SE Australia is difficult; however
745
far field plate tectonic events have been interpreted to produce local deformation by
746
transference of intraplate stresses over large distances in Australia (Dickinson et al.,
747
2001; Sandiford et al., 2004).
748 749 750
7. Conclusions The Cenozoic history of the Gippsland Basin is characterised by two major
751
tectonic regimes. The Late Cretaceous-Eocene period is characterized by
752
extensional tectonics that produced abundant normal growth faults. Analysis of
753
growth strata on these normal faults indicates a general waning of extensional
754
activity from the Late Cretaceous through to the Eocene. During the latest Eocene to
755
early Oligocene (~34 Ma), the tectonic regime changed to one of compression. This
756
compressional tectonic episode continues to the present day in the South Eastern
757
Australian basins. The large anticlines which host the giant oil fields of the Gippsland
758
Basin were all formed during the Oligocene to the Holocene.
759
Detailed analysis of growth strata from anticlines and reverse faults in the
760
Seaspray Group (Oligocene to Holocene carbonates) indicates a significant and
761
widespread episode of compression occurred during the early Oligocene, a period
762
not previously identified as being important tectonically. It appears likely that this
763
Oligocene compressional event also affected other South Eastern Australian basins
764
and was likely a significant component of uplift in the Eastern Highlands.
765
In onshore regions of the basin, a second major pulse of compressional tectonism
766
occurred during the mid-Miocene. In offshore regions, this mid-Miocene event is
767
more subdued, with continued low-level growth on the major anticlines. In nearshore
768
and onshore regions, the late Miocene-Pliocene is characterized by a significant 33
769
unconformity which corresponds to the previously documented episode of tectonic
770
uplift and erosion that began at around 10 Ma (Dickinson et al., 2002). Like the mid-
771
Miocene event, the Late Miocene event has a greater affect in onshore regions, with
772
major uplift occurring on features like the Baragwanath Anticline and Strzelecki
773
Ranges.
774 775 776
Acknowledgements We would like to thank IHS Markit for their donation of the Kingdom seismic
777
interpretation software. E. Mahon is supported by a Baragwanath Geology Research
778
Scholarship, and the Melbourne Research Scholarship as part of the Australian
779
Government Research Training Programme Scholarship, in addition to the AAPG
780
Foundation Grants-in-Aid Chandler and Laura Wilhelm Named Grant, and the
781
Geological Society of Australia (Victorian Division) Postgraduate Grant. We would
782
like to thank two anonymous reviewers and the editor Adam Bumby for their helpful
783
and constructive comments that significantly improved the manuscript.
784
34
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45
Highlights • • •
Estimates for timing of growth for structures in the Gippsland Basin are made A change from extension to compression occurs at ~ Eocene-Oligocene boundary A previously unrecognized early Oligocene tectonic event is documented for SE Australia
E.M.M and M.W.W. conceived the project, E.M.M. compiled the data, interpreted the seismic profiles and analysed the data. E.M.M and M.W.W. interpreted the results and wrote the paper.
Declaration of interests ☒ The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper. ☐The authors declare the following financial interests/personal relationships which may be considered as potential competing interests:
S0264-8172(20)30026-X
DOI:
https://doi.org/10.1016/j.marpetgeo.2020.104243
Reference:
JMPG 104243
To appear in:
Marine and Petroleum Geology
Received Date: 1 August 2019 Revised Date:
16 December 2019
Accepted Date: 13 January 2020
Please cite this article as: Mahon, E.M., Wallace, M.W., Cenozoic structural history of the Gippsland Basin: Early Oligocene onset for compressional tectonics in SE Australia, Marine and Petroleum Geology (2020), doi: https://doi.org/10.1016/j.marpetgeo.2020.104243. This is a PDF file of an article that has undergone enhancements after acceptance, such as the addition of a cover page and metadata, and formatting for readability, but it is not yet the definitive version of record. This version will undergo additional copyediting, typesetting and review before it is published in its final form, but we are providing this version to give early visibility of the article. Please note that, during the production process, errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. © 2020 Published by Elsevier Ltd.
1 2
Cenozoic structural history of the Gippsland Basin: Early Oligocene onset for compressional tectonics in SE Australia
3 4
Elizabeth M. Mahon*, Malcolm W. Wallace
5
School of Earth Sciences, University of Melbourne, Parkville, Vic. 3010, Australia
6 7 8
*Corresponding Author. E-mail address: [email protected] (E. Mahon), [email protected] (M. Wallace)
9 10 11
ABSTRACT The Gippsland Basin contains some of the largest hydrocarbon accumulations in
12
Australia, and has been in production since the 1920’s. These hydrocarbons are
13
trapped by large growth anticlines offshore, in reservoirs of the Cretaceous to
14
Eocene-aged Latrobe Group. Despite the obvious importance of these growth
15
anticlines, the timing of their formation, and the overall Cenozoic tectonic history of
16
the basin is not well understood.
17
Here, we present a detailed growth strata analysis of the faults and anticlines
18
within the Cenozoic sediments of the Gippsland Basin. This indicates two major
19
phases of tectonism in the basin: 1. Late Cretaceous to Eocene extension, and 2.
20
Oligocene to Holocene compression. Detailed analysis of the extensional phase
21
indicates the development of numerous normal growth faults, which display an
22
overall reduction in the magnitude of extension from the Late Cretaceous to the
23
Eocene, commonly terminating at the top of the Latrobe Group. The shift to
24
compressional tectonism occurred at approximately the Eocene-Oligocene boundary
25
(~34 Ma). A major and widespread episode of compression then occurred, with
26
evidence of growth on anticlines and reverse faults beginning in the early Oligocene.
27
This previously unrecognized early Oligocene event produced significant growth (20
28
to 50% total growth) of the major anticlines which host hydrocarbon accumulations.
29
The early Oligocene event represents the first phase of the compressional tectonic
30
regime that continues to the present day in SE Australia. It appears likely that this
31
Oligocene event affected other basins in SE Australia and probably contributed to 1
32
uplift of the Eastern Highlands. The underlying tectonic cause for this Oligocene
33
compressional regime is enigmatic and may be related to far field tectonic
34
processes.
35
A second pulse of compressional tectonism and anticline growth occurred during
36
the mid-Miocene and is generally more significant in the onshore regions of the
37
basin. The youngest phase of compressional tectonism beginning in the Late
38
Miocene (~10 Ma) is also more intense in onshore regions and is marked by an
39
unconformity that is widespread in SE Australia.
40 41 42
Key words: Gippsland Basin; SE Australia; growth strata; basin inversion; seismic; extension; compression; tectonics
43 44 45 46
1. Introduction The Gippsland Basin has been one of the most prolific hydrocarbon-producing
47
regions in Australian history, containing some of the largest hydrocarbon
48
accumulations in Australia. From the discovery of oil onshore in 1924, to the
49
discovery of giant oil and gas fields offshore in the 1960’s, the Gippsland Basin has
50
contributed extensively to the history of hydrocarbon exploration and production in
51
Australia. A great deal of geological research and exploration was carried out in the
52
basin between the 1960’s and the 1990’s. However, despite this attention, there is
53
relatively little published literature on the basic geology of the basin. The position of
54
the basin on the south-eastern corner of the Australian continent has meant it has
55
been subjected to multiple phases of tectonic movement, including rifting along the
56
southern margin of Australia, rifting on the eastern margin of Australia, and Neogene
57
compressional tectonics (Dickinson et al., 2001). There has been some focus on
58
early basin formation (e.g. Gunn, 1975; Threlfall et al., 1976; Etheridge et al., 1985;
59
Lowry, 1988; Lowry and Longley, 1991), and on young tectonism (e.g. Dickinson et
60
al., 2001, 2002). However, the general Cenozoic tectonic history of the basin has
61
not been well documented.
2
62
Hydrocarbon accumulations in the Gippsland Basin are trapped offshore in broad
63
northeast-southwest trending anticlines. Despite the importance of these structures
64
as traps for hydrocarbon accumulations, the timing of the formation of these
65
anticlines is quite poorly constrained. The timing of anticline growth in the Gippsland
66
Basin has been estimated by various authors to a time period anywhere from the
67
Late Cretaceous to the Miocene (e.g. Brown, 1986; Smith, 1988; Maung and
68
Nicholas, 1990; Rahmanian et al., 1990; Duff et al., 1991; Lowry and Longley, 1991;
69
Johnstone et al., 2001; Holford et al., 2011).
70
Sedimentation concurrent with tectonism provides a method to identify the history
71
of structures, and is often referred to as ‘growth strata’ (Childs et al., 2003; Jackson
72
et al., 2017). Measurements of thickness changes of sediment across a structure
73
(fault or fold), in conjunction with chronostratigraphic data (e.g. paleontological
74
information), can provide accurate information regarding the history of growth on the
75
structures (Childs et al., 2003). To date, no studies have quantified tectonic growth
76
episodes on structures in the Gippsland Basin. In this study, we have quantitatively
77
analysed the growth history of structures to determine the timing and intensity of the
78
various structural episodes in the Gippsland Basin. We document a hitherto
79
unidentified episode of major tectonism during the Oligocene that appears to
80
represent the onset of compressional tectonism in South Eastern Australia.
81
2. Geological Setting
82
This Gippsland Basin, located on the southeast corner of the Australian continent,
83
occupies a unique position in Australia’s tectonic history. It is part of a series of rift
84
basins which formed along the southern margin of Australia, as Australia and
85
Antarctica rifted apart in the Late Jurassic to Early Cretaceous (Etheridge et al.,
86
1985). The present day Gippsland basin displays a roughly ESE-WNW-oriented
87
main depocentre, the Central Deep, flanked by the Northern and Southern Terraces,
88
and the Northern and Southern Platforms (Abele et al., 1988). The Northern Terrace
89
is bounded by the Lake Wellington Fault System to the north, and the Rosedale
90
Fault System to the south. The Southern Terrace is constrained by the Darriman
91
Fault System to the north, and the Foster Fault System to the south (Fig. 1).
92
3
93
94 95
Fig. 1. The main structural features of the Gippsland basin (modified from Abele et
96
al., 1988). Seismic lines used in this study are displayed in red.
97 98 99
The Gippsland Basin initially formed as a northeasterly trending en echelon graben system (Willcox et al., 1992; Power et al., 2001) as part of a pre-rift
100
depression that extended along the southern margin of Australia, linking the Otway,
101
Bass and Gippsland Basins (Rahmanian et al., 1990). The basement consists of
102
granites and metamorphics of the Lachlan Fold Belt (Evans, 1986; Willcox et al.,
103
1992). Deposition of the Strzelecki Group began during the Early Cretaceous in the
104
grabens as an immature, syn-rift, volcanoclastic unit, deposited from braided
105
streams and alluvial fans (Threlfall et al., 1976; Rahmanian et al., 1990; Tosolini et
106
al., 1999). By the end of the Early Cretaceous, rifting shifted to southwest of
107
Tasmania, resulting in uplift and an associated unconformity in the Gippsland Basin,
108
and the compartmentalisation of the Otway, Bass and Gippsland Basins (Rahmanian
109
et al., 1990; Power et al., 2001). The Strzelecki Group underwent complex wrench-
110
style deformation at this time (Threlfall et al., 1976; Willcox et al., 1992). During the
111
Late Cretaceous, Zealandia rifted off the eastern side of southeastern Australia, 4
112
opening the Tasman Sea (Mortimer et al., 2019). An angular unconformity
113
associated with this event separates the Strzelecki Group from the overlying Latrobe
114
Group. This unconformity is particularly distinct on the terraces, but becomes
115
conformable in the Central Deep (Threlfall et al., 1976; Featherstone et al., 1991).
116
The Gippsland Basin then underwent a shift from active rifting, to a post-rift,
117
thermal sag phase, during which normal faulting continued but gradually waned
118
(Evans, 1986; Willcox et al., 1992), creating accommodation space for the
119
siliciclastic Latrobe Group. The Latrobe Group has been subdivided into formations
120
by a number of authors (Bodard et al., 1986; Bernecker and Partridge, 2001). Here,
121
we have used a simplified onshore stratigraphic scheme for the Latrobe Group (Fig.
122
2).
123
South-southeast trending canyons up to 650 m deep (Holdgate et al., 2003)
124
incised into the Central Deep during the Early Eocene, forming the Tuna-Flounder
125
and the Marlin-Turrum formations (James and Evans, 1971; Hocking, 1972). The
126
ages of incision and infill of these features is constrained by palynological data from
127
well penetrations, and indicates that the Tuna canyon incised during the M diversus
128
zone (early Eocene) and the Flounder Formation infilled it during the P asperopolus
129
zone (mid Eocene), after which the Marlin channel incised during the P asperopolus
130
zone, cutting into the southwestern side of the Tuna-Flounder Formation, and
131
partially filled with the Turrum Formation during the N asperus zone (Late Eocene).
132
Due to the transgressive nature of the upper Latrobe Group, the upper boundary
133
of the Group is diachronous, and is oldest offshore and youngest onshore. The top of
134
the Latrobe Group is characterized by an interval of condensed marine sediments
135
known as the Gurnard Formation, a thin unit of glauconitic sandstone, deposited
136
discontinuously across the eastern portion of the basin (James and Evans, 1971).
137
Some authors have interpreted the top of the Latrobe Group as a regional
138
unconformity (Rahmanian et al., 1990; Holdgate et al., 2003; Gibson-Poole et al.,
139
2007; Holford et al., 2011) although we favour a diachronous condensed marine
140
origin for this boundary.
141
The Seaspray Group was deposited over the Latrobe Group, and is dominated by
142
non-tropical shallow and deep-water carbonates (James and Evans, 1971; Gallagher
143
et al., 2001; Wallace et al., 2002), with laterally equivalent brown coals and clastic 5
144
interseam sediments onshore. The basal unit, the Lakes Entrance Formation,
145
comprises the first fully marine sedimentation onshore Gippsland Basin (Holdgate
146
and Gallagher, 2003). It consists of shelfal marine muds and limestones, which
147
experienced extensive submarine canyoning in its upper intervals in the central deep
148
of the basin (James and Evans, 1971; Wallace et al., 2002). Overlying the Lakes
149
Entrance Formation is the Gippsland Limestone, which consists of fossiliferous
150
limestone and marl, and their lateral equivalent coastal plain coals and interseam
151
clastics in the Latrobe Valley (Gallagher and Holdgate, 1996).
152
Structures in the Gippsland Basin reflect the multi-phase tectonic history of the
153
Basin. The basin displays predominantly northwest trending extensional faults in
154
deeper parts of the basin, with northeast trending anticlines and some reverse
155
faulting occurring at shallower depths. These anticlines form traps for the major
156
hydrocarbon reservoirs in the upper Latrobe Group offshore. Timing of the initiation
157
of compressional tectonics in the Gippsland Basin (which resulted in growth of these
158
anticlines) is poorly constrained, and is interpreted as beginning in the Late
159
Cretaceous (Duff et al., 1991), early Eocene (Smith, 1988; Johnstone et al., 2001),
160
early-mid Eocene (Brown, 1986; Lowry and Longley, 1991; Holford et al., 2011), or
161
Late Eocene-Miocene (Maung and Nicholas, 1990; Rahmanian et al., 1990). The
162
basin bounding extensional fault systems have experienced inversion to varying
163
degrees along their lengths (Dickinson et al., 2001). A young phase of
164
compressional tectonism occurred in the late Miocene, resulting in uplift of the
165
Strzelecki Ranges and folding of onshore Palaeogene coals (Dickinson et al., 2001;
166
2002).
6
167 168 169
Fig. 2. Major stratigraphic subdivisions of the Late Cretaceous to present sediments
170
in the Gippsland basin (modified from Norvick et al., 2001).
171 172 173
3. Methodology 2D and 3D seismic and well data are available over most of the basin. There are
174
many 3D seismic datasets located offshore, which have been merged into a
175
‘Megacube’ seismic volume. This merged 3D seismic was used to undertake seismic
176
interpretation of faults and horizons. The volume is SEG reverse polarity 7
177
(otherwise referred to as ‘European’ polarity), full stack, and approximately zero-
178
phase. Interpretation of 2D seismic was undertaken on the nearshore and onshore
179
areas (where 3D data was unavailable). Data was obtained from the Geological
180
Survey of Victoria, Australia.
181
Well control in the Gippsland Basin is generally good, with over 400 exploration
182
wells, and many more development wells available. Well logs include gamma ray,
183
sonic, neutron porosity, and neutron density. Biostratigraphic data for the
184
Seaspray Group is derived from planktonic foraminiferal analysis. A zonation
185
scheme for offshore wells was first developed by Taylor (1965a, b, 1966) and later
186
refined by him (e.g. Taylor, 1975, 1977, 1979). This zonation scheme consists of a
187
series of lettered “zonules” (Fig. 2) (discussed in detail in Abele et al., 1988) which
188
can be correlated to international planktonic foraminiferal zonation schemes
189
(Gradstein et al., 2012). Onshore, various biostratigraphic schemes have been used
190
(mainly Carter zones – Carter, 1958a, b) and these can also be correlated to the
191
international scheme of Gradstein et al (2012). Foraminiferal data is derived from a
192
series of unpublished open file biostratigraphic reports that are available for many of
193
the onshore and offshore wells of the Gippsland Basin (largely authored by C. Abele
194
in the onshore and D.J. Taylor in the offshore). The onshore wells Wurruk Wurruk-1
195
and Boole Poole 1 were the subject of a detailed foraminiferal/biostratigraphic study
196
(Holdgate and Gallagher, 1997) and these cored wells can be correlated to nearby
197
wells with electric logs and seismic data.
198
The chronostratigraphic framework for the Latrobe Group is largely derived
199
from palynological spore-pollen and dinoflagellate zonation schemes (James and
200
Evans, 1971; Partridge, 1971; Stover and Evans, 1973; Stover and Partridge,
201
1973; Partridge 1976; Partridge, 1999; Warne et al., 2003; Partridge, 2006) in
202
combination with numerous unpublished palynological reports that are available
203
for most petroleum wells from the Gippsland Basin. These biostratigraphic
204
zonation schemes have here been updated to the Gradstein 2012 time-scale
205
(Gradstein et al., 2012; Korasidis et al., 2018, 2019). Specific wells of importance
206
in this study were Barracouta 3 (Stover and Partridge, 1971), Veilfin 1 (Hannah and
207
Macphail, 1985) and Teraglin 1 (Macphail, 1983).
8
208
Seismic horizons were interpreted across each structure, as closely spaced as
209
data allowed. Regional correlations tied to biostratigraphic data were correlated to
210
each structure and used as biostratigraphic datums for age determination on each
211
structure. The thicknesses (in two-way-time) of the syn-tectonic sedimentary
212
packages were measured at two locations across each structure. For growth
213
anticlines, the crest and hinge locations were used, with preference given to a hinge
214
location that was not separated from the crest by faulting. Intervals were measured
215
vertically, and intervals that have been eroded at the crest of the structure were not
216
included. For growth faults, the footwall and hanging wall were measured as close to
217
the fault as possible. In total, ten different structures were quantitatively assessed for
218
structural growth; the Mackerel, Fortescue, Salmon, and Barracouta extensional fault
219
blocks, and the Dolphin, Barracouta, Golden Beach, Darriman and Baragwanath
220
anticlines, and the Baragwanath fault. The specific structures studied were selected
221
based on their location in the basin, with the aim of gaining a representative spread
222
of geographic areas and structure types. Faults located in the Central Deep of the
223
basin were targeted for analysis. Measurements were taken from the centre of the
224
fault traces, in order to minimise any fault-tip effects which may skew the fault growth
225
analyses. Normal faults that have been inverted were also avoided for growth strata
226
analysis.
227
Thickness measurements of sediment packages across each structure were used
228
to determine the Expansion Index (EI). The EI is a ratio of the thickness of growth
229
sediments between the upthrown (or on-structure) and downthrown (or off-structure)
230
locations (e.g. anticline crest and hinge respectively) (Thorsen, 1963). An EI of 1
231
indicates no growth, while an EI of >1 indicates structural movement and growth
232
sedimentation (Jackson et al., 2017). (1)
233
Expansion Index = a / b (Thorsen, 1963)
234 235 236 237 238
Where: a = twt of individual downthrown package
239
b = twt of individual upthrown package
240 241
(twt = two-way-time)
9
242 243
The EI displays the expansion, or growth of individual sediment intervals.
244
However, it is difficult to assess the relative amount of structural growth from EI data.
245
This is because different thickness (twt) intervals are used for each calculation based
246
on which horizons can be correlated accurately. For example, a relatively thin unit
247
may display a very large expansion index and appear as a significant episode of
248
growth on the plot. However, because the unit is relatively thin, it will represent a
249
very small proportion of total growth on the structure and may be unrepresentative in
250
terms of the overall growth history. Hence we have calculated another function
251
which we have called the Growth % (Fig. 3). The Growth % provides the proportion
252
of total growth on the structure for each interval and this function appears to provide
253
a more quantitative and representative picture of the relative growth on the structure
254
over time. The equation used is as follows. (2)
255
Growth % = ((a – b) / (A – B)) *100
256 257 258
Where:
259
a = twt of individual downthrown package
260
b = twt of individual upthrown package
261
A = twt of total downthrown section
262
B = twt of total upthrown section
263 264
(twt = two-way-time)
265 266
Each growth analysis diagram displays the measured sediment packages and biostratigraphic datums.
267 268
10
269
270 271 272
Fig. 3. Diagram illustrating the variables used in the calculation of the Growth % equation (Equation 2).
273 274 275
4. Uncertainties and Limitations Studies of structural growth on anticlines and faults have used either sediment
276
thickness (e.g. Thorsen, 1963) or two-way-time on seismic profiles (e.g. Mansfield
277
and Cartwright, 1996; Jackson et al., 2017), depending on the data available
278
(seismic, outcrop or wells) and the purpose of the study. Several authors have noted
279
that fault growth plots for faults commonly appear similar whether presented in depth
280
or two-way time, especially if sonic velocity varies gradually with depth and there are
281
no significant lateral velocity variations (Baudon and Cartwright, 2008; Omosanya et
282
al., 2015).
283
In the Gippsland Basin, sonic velocities in the Seaspray Group generally increase
284
gradually with depth. Lateral variations can be present and are related to submarine
285
canyons (Wallace et al., 2002). Using typical velocity gradients for the Seaspray
286
Group (Wallace et al., 2002), we estimate that on the structures with the thickest
287
growth, Growth % plots would underestimate the oldest growth by around 15%.
288
This would mean that our growth plots slightly underestimate the significance of the
289
oldest (Oligocene) growth in the Seaspray Group. This would not significantly affect 11
290
the timing estimates for structural growth presented in this study.
291
in velocity due to the presence of submarine canyons are unlikely to affect our
292
structural growth estimates because such large-scale canyons are visible on seismic
293
images and we have avoided measuring across them. A potential source of lateral
294
velocity variation that might affect growth calculations would be the presence of
295
different lithologies on structural highs (e.g. higher carbonate contents on highs).
296
However, there are no completely off-structure wells to provide a lithologic
297
comparison. Additionally, lateral facies change of this nature would be expected to
298
affect most of the Seaspray Group section and changes in growth rates would still be
299
visible on growth analysis plots. Velocity gradients in the Latrobe Group tend to be
300
lower than those in the Seaspray Group, with consequently lower errors.
301
Lateral variations
Another source of error in estimates of growth on structures is the effect of
302
differential compaction (Mansfield and Cartwright, 1996). Sediments on structural
303
highs are subjected to lower depths of burial and hence less compaction than off-
304
structure sediments. This effect is somewhat related to sonic velocity (as sonic
305
velocity is largely controlled by compaction and porosity), and has the same
306
outcome, resulting in underestimation of the growth history of more deeply buried
307
strata (i.e. Oligocene growth will be underestimated in the Seaspray Group).
308
Interstratal variations in lithology and compaction tend to be cancelled out by the
309
analysis of several different geographic regions and structures.
310
Differential compaction has occurred in the Latrobe Group due to the presence of
311
lateral facies changes. This is particularly evident in the upper interval of the Group,
312
as a result of sand-rich barrier systems. This form of differential compaction has
313
been taken into account in this study, as the sandy barrier systems of the Latrobe
314
Group can be easily recognised on seismic profiles (e.g. Fig. 9 Barracouta Fault,
315
Fig.11 Dolphin Anticline).
316
A source of uncertainty in the relative age of structural growth is the spacing of
317
interpreted seismic horizons and age datums. In the seismic data from the deeper
318
water Seaspray Group, it is commonly difficult to interpret seismic reflectors over
319
large distances due to many small (<50 m deep) erosional features that are related
320
to small-scale submarine canyon systems. Widely-spaced seismic horizons will
321
result in less detailed age determinations for specific growth events.
322 12
323 324
5. Results Analysis of growth across a range of structures was undertaken in the Gippsland
325
Basin. These structures fall into two clear groups: those that occur within the Latrobe
326
Group and those that occur within Seaspray Group. These structures are clearly
327
evident on seismic data as large anticlines and faults (Figs. 4, 5).
328 329
Fig. 4. Top Latrobe Group two-way-time-structure map over the 3D Megacube area
330
(offshore Gippsland Basin). Faults analysedin this study are shown in black. The
331
Dolphin, Golden Beach and Barracouta anticlines (analysed here) are also shown.
332
The white line (Z-Z’) is shown as a seismic section on Fig. 5.
333
13
334 335
Fig. 5. Megacube arbitrary line Z-Z’ (located on figure 4). Latrobe Group faults
336
analysed are depicted in a hard black line. Grey dashed lines indicate bends in
337
seismic profile. See Fig. 4 for line location.
338 339
5.1 Latrobe Group Structures
340
Virtually all faults within the Latrobe Group have growth strata which indicate a
341
normal sense of movement. Normal growth faults are evident on seismic profiles by
342
a thickening of sedimentary packages into the hanging wall of the fault. These
343
normal growth faults are more common offshore, with faults generally terminating at
344
or close to the Top Latrobe Group reflector.
345
The Mackerel fault block is a northwest trending block, which dips to the
346
southwest. It is bound by northwest trending normal faults, which both dip to the
347
northeast. The fault block contains three well penetrations - Halibut 1, Trumpeter 1
348
and Mackerel 3. The growth strata on the southern bounding fault of this fault block
349
were analysed (Fig. 6). At this location the Top Latrobe Group horizon is affected by
14
350
marine erosion on the northern side of the fault block. This is associated with post-
351
Latrobe Group erosion.
352
The Expansion Index plot shows multiple intervals of increased growth, with a
353
maximum EI of 1.5, in the base F longus. The Growth % plot for the Mackerel fault
354
block shows four distinct phases of growth, with an overall reduction in magnitude of
355
growth over time. A feature not readily apparent on the expansion index plot is a
356
large amount of growth at the base of the interval analysed (Late Cretaceous – T
357
lilliei time). On this structure, 39% of the total growth occurred during the mid-Late
358
Cretaceous (T lilliei), 45 % during the late Late Cretaceous (F longus), while only
359
17% occurred during the late Palaeocene (Upper L balmei). The fault terminates at
360
the Top Latrobe Group horizon, when growth was less than 5%.
361
362 363
Fig. 6. 3D Megacube inline 4253 with biostratigraphic datums and showing Mackerel
364
fault block growth analysis. See Fig. 1 for line location.
15
365
The Fortescue fault block is a west-northwest trending fault block, which dips to
366
the south-southwest. It is bound by west-northwest trending normal faults, which
367
both dip to the north-northeast. It contains the wells Fortescue 1, Fortescue 3, and
368
West Halibut 1. The southern fault of this fault block was analysed (Fig. 7).
369
The Expansion Index shows three phases of increased growth. The Growth % plot
370
displays correlative phases of increased total growth to the EI, with the largest
371
growth occurring during the Late Cretaceous (Lower F longus). On this structure,
372
42% of the total growth occurred during the Late Cretaceous (Lower F longus), 21%
373
occurred during the early Palaeocene (Lower L balmei), another 21% occurred
374
during the late Palaeocene (Upper L balmei), and 16% occurred during the middle
375
Eocene (P asperopolus). This again shows a pattern of reduction in growth over
376
time, terminating at the Top Latrobe Group horizon with the cessation of normal
377
faulting.
378 379
Fig. 7. Megacube inline 3807 with biostratigraphic datums and showing Fortescue
380
fault block growth analysis. See Fig.1 for line location.
16
381
The Salmon fault block trends northwest, and dips to the southwest. It is bound by
382
two northwest dipping normal faults, and contains the wells Salmon 1 and Vielfin 1.
383
The southern fault of this fault block was analysed (Fig. 8). The Expansion Index plot
384
has a variable character, with every individual interval displaying growth except the
385
uppermost Latrobe Group (N asperus), which has an EI = 1 indicating no growth.
386
The Growth % plot shows a slightly variable growth character, with growth
387
gradually waning with time. On the Salmon block, 30% of the total growth occurred in
388
the late Palaeocene (Upper L balmei), 46% in the early Eocene (M diversus), 15% in
389
the early-mid Eocene (P asperopolus), and 9% in the late Eocene (Middle N
390
asperus). Normal faulting appears to have ceased at the Top Latrobe Group (middle
391
Eocene - P asperopolus time), with sediments infilling accommodation space (and so
392
showing growth) until just after this time, during the late Eocene (N asperus).
393
394 395
Fig. 8. Megacube inline 2989 with age datums and showing Salmon fault block
396
growth analysis. See Fig.1 for line location.
397
The Barracouta fault block trends west-northwest, and is located on the southern
398
side of the Barracouta anticline. It is bound by a normal fault to the south, and by a
399
(currently) reverse fault to the north. The southern fault was analysed (Fig. 9). The
400
Expansion Index plot has a variable character, though there appears to be two 17
401
phases of increased growth; during the middle Palaeocene (L balmei time), and the
402
mid Eocene (P asperopolus to N asperus time).
403
The Growth % plot for the Barracouta Fault block again shows growth gradually
404
reducing with time. The majority of the growth (73%) occurs in the late Palaeocene
405
(L balmei), and 31% of the total growth occurs during the mid-Eocene (P
406
asperopolus). By late Eocene time (middle N asperus) growth transitions from 18%
407
to negative (i.e. apparent compression). The apparent compression is likely due to a
408
facies change within the Latrobe Group.
409
410 411
Fig. 9. Megacube inline 2057 with biostratigraphic datums and showing Barracouta
412
fault block growth analysis. See Fig. 1 for line location.
413 414
5.2 Seaspray Group Structures
415
Growth anticlines and reverse faults dominate the structures of the Seaspray
416
Group, both in the onshore and offshore regions. On seismic data, thickening of
417
sedimentary packages is evident adjacent to anticlinal structures and thinning over
418
the crest of the anticline. The same is apparent for reverse faults. In contrast to the 18
419
underlying Latrobe Group, there is no evidence of normal faulting within the
420
Seaspray Group.
421
The Barracouta anticline (Fig. 10) is one of the largest structures in the offshore
422
Gippsland Basin. It is a northeast trending structural high, has numerous well
423
penetrations, and contains significant hydrocarbon reserves in the upper Latrobe
424
Group. Basal Seaspray Group sediments which onlap the structure fall within the P
425
tuberculatus palynological zone.
426
The Expansion Index plot for the Barracouta anticline displays a negative EI value
427
at the uppermost Latrobe Group interval, indicating thickening of sediments onto the
428
crest (caused by the presence of sandy barrier facies on the crest of the anticline).
429
This indicates anticline growth likely had not begun yet. Immediately above the
430
Latrobe Group, in the Oligocene to early Miocene, EI values increase abruptly up to
431
9 indicating a large amount of growth. EI values subsequently remain relatively low
432
to the top of the interval analysed, in the mid Miocene (just above Taylor zone C).
433
Above this, the crest of the structure has experienced erosion, evident by truncated
434
reflectors. While growth rate cannot be quantified due to this erosion, it indicates the
435
Barracouta anticline continued growing.
436
The Growth % plot for the Barracouta anticline shows a similar pattern. Growth is
437
negative in the uppermost Latrobe Group, due to pre-anticline facies distribution in
438
the Latrobe Group. Beginning quite abruptly above the middle N asperus-Top
439
Latrobe Group reflector is a significant pulse of growth. Here, 64% of the total
440
growth of the Barracouta anticline occurred in the Oligocene-early Miocene - the
441
majority of which occurred in the Oligocene. Moderate growth occurred during the
442
mid-Miocene, remaining below 20%. Growth was reduced significantly in the late
443
Miocene, remaining below 5%. Subsequent Late Miocene-early Pliocene growth is
444
inferred by erosion of the anticline crest after this time.
445
19
446
447 448
Fig. 10. Megacube inline 2079 with key horizons, showing Barracouta anticline
449
growth analysis. See Fig.1 for line location.
450
The Dolphin anticline (Fig. 11) trends northeast, and is located south of the
451
Barracouta anticline. Basal Seaspray Group sediments which onlap the structure are
452
interpreted as Taylor zone J1. The Expansion Index plot for the Dolphin anticline
453
displays growth in the upper Latrobe Group (middle N asperus, Late Eocene).
454
However, this apparent structural growth is due to a lateral facies change within the
455
Latrobe Group, rather than structural growth (a middle N. asperus sandy barrier is
456
present in the syncline). The EI remains above 1 until the mid Miocene (Taylor zone
457
C). After this time it drops below 1, indicating no growth of the structure. Above this,
458
the Dolphin Anticline has experienced erosion at the crest, evident by an angular
459
unconformity at or close to the seafloor. This erosion is indicative of anticline growth,
460
though it can’t be confidently quantified.
461
The Growth % plot for the Dolphin anticline indicates 48% of the total growth
462
occurred during the Oligocene to Early Miocene (between the N asperus and Taylor
463
zone G times). Growth on the structure gradually reduced during the Miocene, 20
464
although 37% of the total growth occurred during this time (Taylor zone G to Taylor
465
zone C). Above this, growth becomes negative. This is likely reflecting lateral
466
sedimentation changes, and not structural movement. Above this, an erosional
467
surface is evident, indicating growth of the anticline again.
468
469 470
Fig. 11. Megacube arbitrary line with biostratigraphic datums, showing Dolphin
471
anticline growth analysis. See Fig.1 for line location.
472
The Golden Beach anticline (Fig. 12) is located close to the present-day coastline,
473
and trends northeast. It has multiple well penetrations, including Golden Beach 1.
474
Basal Seaspray Group sediments are dated at Taylor zone K. The Expansion Index
475
plot for the Golden Beach anticline displays EI values of 1 in the upper Latrobe
476
Group, indicating no anticlinal growth. Above this, the EI is highly variable in value,
477
ranging from just above 1, up to almost 6. The largest EI occurs in the mid Miocene
478
(just above Taylor zone G). EI does not drop below 1, indicating growth to the top of
479
the interval analysed, in the mid Miocene. Above this, erosion is evident by an 21
480
angular unconformity just below the sea floor, again, indicating continued anticline
481
growth.
482
The Growth % plot shows almost no growth in the upper Latrobe Group, then a
483
sudden onset of growth immediately above the Top Latrobe Group reflector, in the
484
basal Seaspray Group. 59% of the total growth occurs in the Oligocene-early
485
Miocene, the majority of which occurs in the Oligocene. The Growth % is variable
486
after this time, with 26% occurring in the early-mid Miocene (Taylor zone G to Taylor
487
zone C). Growth % remains positive to the top of the interval analysed.
488
489 490
Fig. 12. 2D seismic line GGS185AE-02 with biostratigraphic datums and showing
491
Golden Beach anticline growth analysis. See Fig. 1 for line location.
492
The Darriman Anticline (Fig. 13) is located in the southern area of the onshore
493
Gippsland Basin. It is associated with one of the main bounding faults of the
494
southern margin of the basin, the Darriman Fault System. Measurements were taken
495
on the northern side of the anticline. Expansion Indices for the Darriman Anticline are
496
variable, although they do not display the very high indices of offshore anticlines. 22
497
Except for a short interval in the mid Miocene, EI values remain above 1, indicating
498
continued growth of the anticline. Indices are largest immediately above the Latrobe
499
Group reflector (approximately Eocene-Oligocene boundary), and during the mid
500
Miocene. The present day land surface is an angular unconformity. This indicates
501
continued growth on the structure which post-dates the youngest strata in the section
502
(~10 Ma).
503
The Growth % plot shows minor growth in the upper Latrobe Group, similar to
504
Dolphin 1. This is again interpreted as a result of lateral facies changes within the
505
Group. Overall, the Growth % reflects a similar pattern to EI, displaying a period of
506
increased growth immediately above the Latrobe Group reflector, in the Oligocene
507
basal Seaspray Group, and again in the mid Miocene. Growth in the Oligocene to
508
early Miocene accounts for 37% of the total growth of the anticline, while 33% of
509
growth occurred in the mid Miocene (Taylor zone G to Taylor zone C), and 21 %
510
occurred in the late mid Miocene.
511
512 513
Fig. 13. 2D seismic line GCR87B-101 and GCR87B-101a with biostratigraphic
514
datums and showing Darriman anticline growth analysis. See fig. 1 for line location. 23
515
The Baragwanath anticline is a large anticline trending roughly east-west across
516
the onshore section of the Gippsland Basin, and has many well penetrations (Fig.
517
14). The Expansion Index plot for the Baragwanath Anticline shows EI’s consistently
518
>1, which range from 1.5 to 3.5. The interval with the largest EI occurs in the
519
Oligocene (EI =3.5). Above this, sediments are truncated by surface erosion at the
520
crest of the structure, indicating continued structural growth.
521
The Growth % plot for the Baragwanath Anticline shows a small (EI =2) amount of
522
apparent growth in the upper Latrobe Group (again, due to a stratigraphic feature- an
523
unconformity over the Latrobe Group). Growth % increases above this, and although
524
not with the distinct sudden onset characteristic of the offshore structures, the time
525
of maximum growth – 41% occurs during the early Oligocene. On this structure,
526
13% of growth occurs during the early Miocene, and 27% during the mid Miocene.
527
528 529
Fig. 14. 2D seismic line GHG-85a-4 biostratigraphic datums and showing
530
Baragwanath anticline growth analysis. See Fig. 1 for line location.
531
The Baragwanath Anticline has two similar-trending reverse faults along its
532
southern side, which roughly parallel the trend of the anticline. The easternmost of
533
these two faults was analysed for growth rates (Fig. 15). The Expansion Index plot
534
for the Baragwanath Fault shows only minimal growth, with EI values only slightly
24
535
above 1. The interval with the largest EI is immediately above the Top Latrobe Group
536
reflector (in the early Oligocene), where EI=1.2.
537
The Growth % plot shows negative to low growth in the upper Latrobe Group
538
during the early Oligocene (Upper N. asperus and older), then sudden, significant
539
growth during approximately the early Oligocene, gradually reducing to almost zero
540
by the end Oligocene. Oligocene growth accounts for 60 % of the total growth of the
541
structure. In the early Miocene growth increased suddenly again, and with the
542
exception of a short period of no growth in the mid Miocene, growth continued.
543
Miocene growth contributed 44 % to the total growth.
544
545 546
Fig. 15. 2D Seismic line GHG85a-3 with biostratigraphic datums, and showing
547
Baragwanath Fault growth analysis. See Fig. 1 for line location.
548 549 550 551
6. Discussion Growth % plots for the Gippsland Basin in the Late Cretaceous and Cenozoic display two major phases of tectonic activity. The Latrobe Group is exclusively 25
552
dominated by normal growth faulting, indicating an extensional tectonic regime.
553
Growth across these faults is evident from the oldest intervals analysed (Late
554
Cretaceous – T lilliei), to the youngest Latrobe Group intervals analysed (Late
555
Eocene – end Lower N asperus). In contrast, the Seaspray Group is dominated by
556
reverse growth faults and growth anticlines, indicating a compressional tectonic
557
regime. Growth on these compressional structures appears to begin at
558
approximately the Eocene-Oligocene boundary (~34 Ma), and continues to the
559
youngest intervals analysed (late Miocene – Taylor zone C). Thus, the transition
560
from extensional to compressional regimes occurs during the Latest Eocene to early
561
Oligocene (~34 Ma). Fig. 16 shows a summary of the growth history of all structures
562
analysed in this study in the Gippsland Basin.
563
564 565
Fig. 16. Plot of structural growth in the Gippsland Basin from the Late Cretaceous to
566
the late Miocene, based on growth % plots from each of the structures analysed.
567
Structures appear to undergo a shift from dominantly extensional to dominantly
568
compressional at around the Eocene-Oligocene boundary ~34 Ma. C, E2, G, H1
569
from Taylor foraminiferal zonation scheme. 26
570 571 572 573
6.1 Extensional Structures Extensional structures in the Gippsland Basin are constrained to the Latrobe
574
Group (and older) sediments. Normal faults in the Latrobe Group show clear
575
thickening of sediments into the hanging wall of these faults. In general, structural
576
growth reduces in magnitude over time, ceasing in the mid to late Eocene (Fig. 16).
577
The Growth % plots for these faults have a generally irregular, ‘pulsed’ appearance.
578
This pulsed or episodic growth character may be due to intermittent fault movement
579
related to the building and release of strain on the fault (Ren et al., 2013).
580
Alternatively, the pulsed appearance might be due to accommodation of strain
581
shifting to other faults in the region.
582
Episodic fault displacement created accommodation space for Latrobe Group
583
sediments in stages, resulting in alternating periods of growth and no growth of
584
sediments across the fault. This episodic fault behaviour has been documented on
585
faults in other basins (Wallace, 1987; Nicol et al., 2005; McClymont et al., 2009;
586
Jackson and Rotevatn, 2013). There appears to be no uniformity in the timing of
587
displacement on the normal faults, nor any relationship to location in the basin.
588
Displacement events on extensional faults appear to have occurred at different times
589
in different parts of the basin. The only observable trend in normal fault growth
590
across the basin is a general waning during Latrobe Group deposition.
591
The data presented here show that extensional faults terminate at or very close to
592
the Top Latrobe Group reflector. However, the Top Latrobe Group is a diachronous
593
horizon, being oldest in the Central Deep to the east and youngest onshore to the
594
west. Given the shift from an extensional to a compressional regime appears to be a
595
regional event, it is reasonable to assume that the youngest sediments showing
596
offset by normal faulting are indicative of when extensional faulting ceased. Thus
597
extensional tectonics in the Gippsland Basin appears to have ended in the latest
598
Eocene.
599
27
600
6.2 Compressional Structures
601
Analysis of growth strata from this study indicate that the tectonic regime in the
602
Gippsland Basin changed from extensional to compressional during latest Eocene to
603
earliest Oligocene time (~34 Ma). The major outcome of this compression was the
604
formation of broad, roughly northeast-southwest trending anticlines in the Central
605
Deep, which today host major hydrocarbon accumulations in the basin (Dickinson et
606
al., 2001). This compressional regime continued into the Neogene, and in addition to
607
anticline formation, reactivation and inversion of previously extensional faults within
608
the Latrobe Group occurred. The Baragwanath Fault (a reverse fault, Fig. 15)
609
displays episodic growth similar to normal faults in the Latrobe Group, as opposed to
610
the more continuous growth behaviour evident on the anticlines.
611
The anticlines studied here generally display two major pulses of growth. The first
612
began at approximately the Eocene-Oligocene boundary (~34 Ma) and continued to
613
the early Miocene (~20 Ma). Where finer scale correlation across structures allows
614
for a more precise timing (e.g. Darriman Anticline, Fig. 13), a large amount of this
615
growth is observed to occur in the early Oligocene. During the Oligocene to early
616
Miocene, anticlinal growth occurred on both onshore and offshore structures, with
617
the magnitude and proportion of growth varying between structures. A second phase
618
of anticlinal growth occurred in the mid-Miocene, and appears to have largely
619
affected onshore anticlines. Offshore structures, however, did not experience this
620
second pulse of increased growth so strongly (or at all in some cases), and instead
621
appear to have remained in a low growth phase from the early Miocene (~20 Ma),
622
until at least the Miocene-Pliocene boundary. At this time erosion is evident,
623
indicating the anticlines began growing again.
624
Concurrent with early anticline growth was deposition of the Seaspray Group. The
625
lower Seaspray Group shows onlap onto the major anticlines and thinning of upper
626
intervals over anticline crests (e.g. Fig. 10, Barracouta anticline), clearly indicating
627
anticlines were growing at the same time deposition was occurring. Despite these
628
compressional events, the basin was still subsiding. Sediments of the Seaspray
629
Group were deposited in deep marine environments (in the offshore part of the
630
basin), characterised by marine calcareous muds and limestones (Holdgate and
631
Gallagher, 2003). The offshore Seaspray Group is characterized by abundant 28
632
submarine canyons (Wallace et al., 2002) indicating an outer shelf and slope setting.
633
A common theme evident on Growth % charts for each structure is a very large and
634
sudden onset of growth in the early Oligocene. This first phase of compression,
635
occurring from the early Oligocene to early Miocene, displays the most growth
636
across both onshore and offshore structures. Brown (1986) suggested that the
637
Dolphin anticline likely had relief in the early stages of post-Latrobe Group
638
sedimentation, due to thinning of sediments toward the anticline. Dickinson et al.,
639
(2001) also noted the onlap and thinning of Oligocene sediments across some of the
640
large offshore anticlines, indicating structural growth at that time. After deposition of
641
the Latrobe Group, there was a period of low sedimentation evident from
642
palynological data showing condensed intervals (and localised, brief unconformities),
643
and deposition of the glauconitic Gurnard Formation. The sudden onset of the first
644
early Oligocene compressional phase may in part reflect reduced sedimentation at
645
the top Latrobe Group-lower Seaspray Group boundary. However, there is no
646
evidence of onlap or thinning of Latrobe Group sediments over the anticlines. In
647
addition, faulting remains extensional until the late Eocene, which suggests that
648
compression and subsequent anticline growth did not occur before this.
649
Previous interpretations of the major hydrocarbon-bearing anticlines of the
650
Gippsland Basin beginning to develop in the early to mid-Eocene appear to be based
651
on the interpretation of large, incised canyons (i.e. the Marlin and Tuna canyons) in
652
the Latrobe Group as resulting from fluvial incision (e.g. Hocking, 1972; Brown
653
1986). This interpretation of deeply incised fluvial canyons implies significant uplift of
654
the basin and hence possible compression during the mid-Eocene. This
655
interpretation first appears in some earlier papers on the Gippsland Basin (Hocking,
656
1972; Threlfall, 1976) at a time when seismic and well data were limited in the
657
Gippsland Basin. There is no evidence to suggest that the Marlin-Turrum and Tuna-
658
Flounder canyons are the result of fluvial incision, and are perhaps of submarine
659
incision origin (as are the abundant canyons in the overlying Seaspray Group). If
660
these canyons were of submarine origin, they are likely unrelated to tectonic uplift.
661
Importantly, there is no evidence for regional unconformities of mid Eocene age
662
within the Latrobe Group. Regardless of the origin of the mid-Eocene canyon
663
systems, there is also no evidence for anticline growth during Latrobe Group time.
29
664
Furthermore, the canyon fill is cut by normal faults (showing extension occurring
665
after infilling) and is subsequently deformed by folding.
666
In the offshore Gippsland Basin, the Oligocene compressional event essentially
667
ceased in the early Miocene, with the Dolphin, Barracouta and Golden Beach
668
anticlines experiencing significantly reduced growth. This low growth of structures
669
persisted to the youngest sediments analysed, in the late Miocene. It is assumed to
670
continue to at least the Miocene-Pliocene boundary, as on seismic lines, structural
671
highs appear peneplained (e.g. Dolphin anticline – Fig. 11). Where seismic
672
resolution allows, this appears as an angular unconformity overlain with horizontal
673
strata. This unconformity coincides approximately with the Miocene-Pliocene
674
boundary, and is particularly evident on the Golden Beach structure (Figs. 12,17).
675
Dickinson et al., (2001, 2002) discussed the Miocene-Pliocene unconformity in
676
detail, observing it in the Murray, Otway, Torquay and Port Phillip Basins, as well as
677
the Gippsland Basin. They also documented erosion of anticlines from shallow
678
seismic data.
679
In the onshore Gippsland Basin, structures underwent a second phase of growth,
680
beginning in the middle Miocene and lasting until the youngest sediments analysed,
681
in the late Miocene. This second phase of compression is not seen in offshore
682
structures. This pattern of more intense structural development onshore continues
683
into the younger tectonic regime. The Late Miocene-Pliocene episode of tectonics is
684
also more intense in onshore settings than in the offshore. In the onshore Latrobe
685
Valley, hundreds of meters of uplift and erosion occurred, with significant uplift of the
686
Strzelecki Ranges (Dickinson et al., 2001, 2002). While the Late Miocene-Pliocene
687
tectonic episode did affect the offshore, it was significantly less intense than in the
688
onshore.
689
30
690 691
Fig. 17. Interpretation of 2D seismic line GGSI85AE-02, which crosses the Golden
692
Beach structure at the northeastern end of the seismic line. Note the thinning of the
693
Oligocene-Miocene interval over the anticline.
694 695 696
6.3 Cenozoic tectonics in SE Australia Australia is commonly regarded as having an insignificant record of Cenozoic
697
uplift and tectonics, with ancient landscapes dominating the geomorphology (e.g.
698
Pain et al., 2012). Some authors have suggested Mesozoic ages for many Australian
699
landscape features like the Southeast Highlands (e.g. Vandenberg, 2010; Webb,
700
2017), while others have suggested much younger tectonic events have been
701
important in SE Australia (Dickinson et al., 2002; Holdgate et al. 2008). The origin of
702
the Southeast Highlands is historically a contentious area of research, with authors
703
proposing old origins for the uplift (uplift in the Mesozoic, e.g. Vandenberg, 2010),
704
very young origins (uplift in the Plio-Pleistocene, e.g. Andrews, 1910) or continuous 31
705
uplift since the Mesozoic (e.g. Wellman, 1979). However, some researchers have
706
argued for a largely post-Eocene origin for this uplift (e.g. Browne, 1969; Holdgate et
707
al., 2008). Recent research undertaken by Greenwood et al., (2017) on vegetation
708
type of the Highlands through geologic time is consistent with a significant episode of
709
post-Eocene uplift affected the SE Highlands. It has been suggested that up to 50%
710
of the present-day topographic relief in the Southeast Highlands formed in the last 10
711
Ma (Braun et al., 2009). Given that the younger tectonic events in the Gippsland
712
Basin (mid-Miocene and Late Miocene-Pliocene) appear to be more intense in
713
onshore positions, it appears likely that post-Eocene compressional tectonics
714
(including the early Oligocene event documented here) and uplift have affected the
715
SE Highlands inshore from the Gippsland Basin.
716
The Oligocene compressional event documented here appears to be a significant
717
event in the Gippsland Basin and almost certainly affected other areas in SE
718
Australia. Evidence for this compressional tectonism has been documented in
719
surrounding basins. The Bass Basin, located immediately southwest of the
720
Gippsland Basin, displays a series of hydrocarbon-bearing anticlines which formed
721
during the Oligocene-Miocene as a result of transpressional inversion (Cummings et
722
al., 2004; Leech et al., 2008). West of the Bass Basin, the Torquay Sub basin of the
723
Otway Basin displays anticlines which began growing in the Oligocene and
724
underwent a second phase of inversion in the Miocene (Young et al., 1991). An
725
angular unconformity is also evident in the onshore Torquay Sub basin, in the
726
Anglesea coal mine, which has been dated palynologically at ~39-40 Ma (Holdgate
727
et al., 2001). This unconformity is believed to be related to significant late Eocene
728
uplift, associated with the Otway Ranges (Holdgate et al., 2001).
729
There is some uncertainty surrounding the cause of the initiation of compressional
730
tectonism in SE Australia. Previous interpretations which have placed the timing of
731
compression earlier (early-mid Eocene) have linked it with the onset of fast sea floor
732
spreading in the Tasman Sea (e.g. Lowry and Longley, 1991; Norvick et al., 2001;
733
Holford et al., 2011; Holford et al., 2014). However, data presented here shows
734
compression likely initiated approximately 10-15 Ma later, at (or close to) the
735
Eocene-Oligocene boundary. At this time, there were a number of smaller tectonic
736
events which affected the continental margins of Australia. These include:
737
development of the Solomon Sea and Caroline Plate on the northeast margin of the 32
738
Australian Plate (Honza et al., 1987; Smith, 1990), oceanic spreading at the South
739
Tasman and Emerald Basins southwest of NZ (Lebrun et al., 2003), and the final
740
separation of Australia and Antarctica at the South Tasman Rise, directly south of
741
the Gippsland Basin (Hill and Exon, 2004; Scher et al., 2015). There is also evidence
742
for a significant unconformity and reverse fault movement on the Lord Howe Rise at
743
around the Eocene-Oligocene boundary (Sutherland et al., 2010). Identification of
744
the exact driver for the initiation of compression in SE Australia is difficult; however
745
far field plate tectonic events have been interpreted to produce local deformation by
746
transference of intraplate stresses over large distances in Australia (Dickinson et al.,
747
2001; Sandiford et al., 2004).
748 749 750
7. Conclusions The Cenozoic history of the Gippsland Basin is characterised by two major
751
tectonic regimes. The Late Cretaceous-Eocene period is characterized by
752
extensional tectonics that produced abundant normal growth faults. Analysis of
753
growth strata on these normal faults indicates a general waning of extensional
754
activity from the Late Cretaceous through to the Eocene. During the latest Eocene to
755
early Oligocene (~34 Ma), the tectonic regime changed to one of compression. This
756
compressional tectonic episode continues to the present day in the South Eastern
757
Australian basins. The large anticlines which host the giant oil fields of the Gippsland
758
Basin were all formed during the Oligocene to the Holocene.
759
Detailed analysis of growth strata from anticlines and reverse faults in the
760
Seaspray Group (Oligocene to Holocene carbonates) indicates a significant and
761
widespread episode of compression occurred during the early Oligocene, a period
762
not previously identified as being important tectonically. It appears likely that this
763
Oligocene compressional event also affected other South Eastern Australian basins
764
and was likely a significant component of uplift in the Eastern Highlands.
765
In onshore regions of the basin, a second major pulse of compressional tectonism
766
occurred during the mid-Miocene. In offshore regions, this mid-Miocene event is
767
more subdued, with continued low-level growth on the major anticlines. In nearshore
768
and onshore regions, the late Miocene-Pliocene is characterized by a significant 33
769
unconformity which corresponds to the previously documented episode of tectonic
770
uplift and erosion that began at around 10 Ma (Dickinson et al., 2002). Like the mid-
771
Miocene event, the Late Miocene event has a greater affect in onshore regions, with
772
major uplift occurring on features like the Baragwanath Anticline and Strzelecki
773
Ranges.
774 775 776
Acknowledgements We would like to thank IHS Markit for their donation of the Kingdom seismic
777
interpretation software. E. Mahon is supported by a Baragwanath Geology Research
778
Scholarship, and the Melbourne Research Scholarship as part of the Australian
779
Government Research Training Programme Scholarship, in addition to the AAPG
780
Foundation Grants-in-Aid Chandler and Laura Wilhelm Named Grant, and the
781
Geological Society of Australia (Victorian Division) Postgraduate Grant. We would
782
like to thank two anonymous reviewers and the editor Adam Bumby for their helpful
783
and constructive comments that significantly improved the manuscript.
784
34
785 786
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45
Highlights • • •
Estimates for timing of growth for structures in the Gippsland Basin are made A change from extension to compression occurs at ~ Eocene-Oligocene boundary A previously unrecognized early Oligocene tectonic event is documented for SE Australia
E.M.M and M.W.W. conceived the project, E.M.M. compiled the data, interpreted the seismic profiles and analysed the data. E.M.M and M.W.W. interpreted the results and wrote the paper.
Declaration of interests ☒ The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper. ☐The authors declare the following financial interests/personal relationships which may be considered as potential competing interests: