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The Motunau Fault and other structures at the southern edge of the Australian-Pacific plate boundary, offshore Marlborough, New Zealand
Tecrono&r,ts.
133
88 (1982) 133-159
Elsevier Scientific
Publishing
THE MOTUNAU
Company,
Amsterdam--Printed
FAULT AND OTHER STRUCTURES
EDGE OF THE AUSTRALIAN-PACIFIC MARLBOROUGH,
R.M. CARTER Department
AT THE SOUTHERN
PLATE BOUNDARY,
OFFSHORE
NEW ZEALAND
* and L. CARTER
of Geology, James Cook Universit~y, TownsviNe (Australw)
New Zealand Oceanographic (Received
in The Netherlands
Institute,
P.O. Box 12346, Wellington (New Zealand)
April 13. 1981; revised version
accepted
February
24. 1982)
ABSTRACT
Carter.
R.M. and Carter,
Australian-Pacific The boundary Alpine
Fault.
L., 1982. The Motunau
plate boundary, between
offshore
the Indo-Australian
then links northeastwards
Fault and other structures Marlborough,
at the southern
New Zealand.
and Pacific
with the Hikurangi
plates
passes
subduction
through
margin
transcurrent
faults. The southern
shear zone is situated
a previously
unrecognized
offshore
of the Motunau
Fault,
Porters
Pass Fault
and lineation
(Cretaceous-Cainozoic) formed
data collected evidenced
that underlie
“Tangaroa”
by complexly
by the presence
of deformed
epicentres.
Within
the Marlborough
plate
blocks,
or “microplates”.
20-60
sediments
Inland
Kaikoura.
are most strongly
within each microplate. pattern
being consistent
and geophysical
boundary
causing
right to the southern microplate.
as faults
further
epicentres
Kaikoura
movement
and other
and folding
strata
continue
and Conway
strike-slip
and faulting,
of the Marlborough
Trough.
where the motion
only reach to intermediate
beneath
margin
0040.
University
of Otago,
I95I /X2/0000-0000/$02.75
Dunedin,
to the plate boundary
New Zealand.
i I982 Elaevier Scientific
Publishing
Company
four
Sequence
fault systems; marine
geologic
southwards
durmg
is occurrmg
to the Motunau
t.he southern
developing.
* Formerly
Kaikoura
subduction
is transferred
depths
delimit
to south. these
the overall structural
fault system is not such a continuous
it is likely that this southern
faults
The available
faults. Today,
as
of earthquake
north
blocks respectively.
folding
undegeologtc
of the Motunau
and by the distribution
on the boundary-faults.
Sequence
marine
of the blocks and their subsidiary
to moderate
of the active
in this area today,
of the Pacific plate may have propagated
activation
and since the Motunau
north,
extension
the Kaikoura
shelf are effectively
records
zone the five major
near the margins
head of the Hikurangi
Since earthquake
Conway
successive
limit of the Marlborough
km wide and up to 220 km long. From
is restricted
with dextral
Faulting
late Pleistocene
data suggest that subduction
the late Neogene. system.
deformation
continental
as the
the Marlborough
1097 and 1116 show that the shelf north
sediments.
Seaward
deformed
the Canterbury
zone. 3.5 kHz profiler
Cruises
deformed
substantial
are the Spenser.
To the south
of the plate boundary
on G.R.V.
fault is underlain
system.
sediments
and lie outside
Fault,
New Zealand
through
shear zone. a group of five major, subparallel at the Motunau
edge of the
Tecfonoph.vsics. 88: 133- 159.
physiographic
fault
part of the features
zone is still actively
134
INTRODUCTION
The New Zealand that between connected
Alpine
Fault marks one of the Earth’s major plate boundaries.
the Indo-Australian
to the Hikurangi
and Pacific plates.
Trough
subduction
The north
complex
end of the fault is
by the Marlborough
shear
zone, comprising several large dextral faults splaying northeast from the main Alpine-Wairau Fault (Fig. 1). Walcott has shown from geodetic data that the major faults of the Marlborough shear zone only accommodate about half of the observed modem strain, and that “at least half the movement.. . may be made up of displacements
on numerous
minor
faults, rotation
ductile flow in the crust” (Walcott, Within the terms of plate-tectonic
MOBIL
GULFREX
of blocks between
1978, p. 153). models, the Alpine
the major faults or by
Fault is considered
today as
1972
1973
42’
Fig. 1. Regional bathymetric
locality
profiles
as in the original
map for northeastern
available
track charts:
South
Island
for the Canterbury-Marlborough an uncertainty
of position
showing
the positions
shelr. (Oil-company
of al least
of the seismic profiles
e 2 km is possible.)
and
are plotted
135
a trench-trench major
Hikurangi seismic,
transform
element
(McKenzie
of compression
Trough,
a filled trench
sedimentologic
and
and Morgan,
developed (Katz,
structural
(Scholz
1969), along which
et al., 1973; Lensen,
1974) is situated features
there is a 1975). The
just east of the volcanic,
of the North
Island
subduction
complex (Cole, 1978; Hatherton, 1980; Lewis, 1973, 1980). The Marlborough shear zone between is less well understood. Though most writers agree that the Marlborough faults are dominantly strike-slip, opinion is divided as to how the faults were initiated, and as to whether all faults of the system are equally active or whether they have developed sequentially to the south in response to changing plate motions (Scholz et al., 1973). The precise way in which subduction changes
to dominantly
strike-slip
motion
on the Hikurangi
in the Marlborough
shear
under
discussion;
Arabasz
and Robinson
(1976) show that deep crustal
define
a dipping
Benioff
zone
the more
Fig. 2. Structural
map of the north
data
(1964).
from Gregg
beneath
Canberburlv-hlarlborough
northerly
faults
shelf and adjacent
margin
zone is also earthquakes
of the system,
areas onland.
Onland
136
whereas
Lewis (1980)
argues
that the southern
west of where it swings in towards
portion
the Marlborough
of the Hikurangi coast, is largely
Trough.
a transform
feature. The southern boundary
1979; Sporli, and
margin
of the Marlborough
zone, has traditionally 1980). G.R.V.
1116 (December,
the continental
“Tangaroa”
1980) included
the shelf in this region, uplifted.
Deformation
of the Hope Fault.
to the
1979)
and sampling
These data,
together
profiles (e.g. Mobil, shear zone continues
by growing
abruptly
of the plate (e.g. Suggate.
1097 (August-September,
of seismic profiling
petroleum company with the Marlborough
which is underlain terminates
with the Hope Fault
Cruises
periods
shelf to the southeast
unpublished but freely available show that deformation associated
shear zone, and therefore
been identified
on with
1972), across
folds and is being actively
southeast
along
a previously
unmapped, major fault of the Marlborough shear zone, the Motunau fault system (Fig. 2). We take the opportunity here to describe this feature and its associated structures,
and to comment
THE MOTUNAU
FAULT
on the regional
significance
of these new data.
SYSTEM
The Motunau Fault occurs as a major bathymetric feature crossing the continental slope about half way between Banks and Kaikoura peninsulas (Figs. 2-3). Near latitude 43”s the fault trends NE and is marked by a narrow gutter, up to 200 m deep, separating a flat-topped spur from the upper parts of the continental slope, themselves steep and continuous with the western wall of the gutter (Fig. 3, Line T4). At its eastern end the fault passes into north-trending faults that extend along the continental slope to define the eastern side of Conway Ridge. The infrequency of suitable satellite passes over New Zealand means that there is considerable uncertainty in the location of the available deep seismic lines in this vicinity (? c. 2 km). Nonetheless, we infer that profiles Mobile 72-4 (Fig. 4) and Gulfrex
76 (Fig. 5) cross the Motunau
Fault.
The continental dipping sequence
shelf and upper slope (Figs. 4-5) are underlain by an eastward of Cretaceous-Cainozoic rocks which can be divided into two
seismic sequences
across a mid-Cainozoic
unconformity.
Below the unconformity
lie
complexly folded and faulted strata of the Onekakara Group (Carter, 1977), a marine transgressive sequence that developed across eastern South Island between the Late Cretaceous and Oligocene. Above the unconformity lie less deformed, but still folded and faulted, strata equivalent to the Otakou Group, which represents the eastward propagation of the eastern South Island late Cainozoic continental shelfslope complex, a regressive sedimentary sequence which formed consequent upon uplift along the plate boundary zone further west (e.g. Walcott and Cresswell, 1979). By analogy with nearby onland sequences (e.g. Prebble, 1980) the unconformity is probably of early middle Miocene age, and marks the start of tectonically controlled sedimentation associated with the development of the Mariborough shear zone (Carter and Norris, 1976).
137
‘. Kai koura
Motunau Fault
Fig. 3. Bathymetric
profiles
across
the continental
margin
betwern
the Conway
and Hurunui
Kl~ers iwc
Fig. 1 for location).
This bipartite
sedimentary
sequence
is truncated
to the east by a deep-seated
and
active fault which displaces the sea-floor by about 200 m, and is associated with a number of smaller, shallow faults further east still. The sedimentary sequence to the east of the ~otunau Fault comprises gently deformed sediments with entirely different reflection characteristics to those west of the fault, their regularly reflecting nature suggesting they form part of the late Cainozoic Trough (cf. Katz, 1974; Lewis, 1980).
turbiditic
fill of the Hikurangi
Fig. 4. Line interpretatians
of deep seismic profiles
Mobil 72-3 and 72-4
0
(a) LINE
5
72 -3
10 15 km
5s
4s
33
2s
15
OS
139
20 km
10
Fig. 5. The Motunau
Extension
Fault as seen on deep seismic profile Gulfrex
76. (Ignore
multiple
reflection,
WI)
landwards across the shelf
South of latitude 43’S the Motunau Fault bends rapidly and traverses continental shelf in a more nearly easterly direction. Few deep seismic profiles
the are
available from this region (Fig. l), making it difficult to specify the exact location of the fault. However, the Motunau Fault is inferred to run up the sea-valley seen on line T4 (Figs. 1, 3) and to continue westwards to link with faults on the same trend on the inner shelf (Fig. 2). (An alternative interpretation would be that the inner shelf and slope features Despite
represent
discrete
but broadly
the lack of deep seismic cover, a number
which cross the projected lines cover the region following facts:
extension
cohnear
faults.)
of 3.5 kHz profiles
are available
of the fault across shelf, and a number
to the northwest
of the fault. These profiles
of other
demonstrate
the
(1) The shelf sector of the Motunau fault does not involve appreciable displacement of the sea-floor, at least by comparison with that seen on the continental slope. (2) A dramatic change in tectonic style takes place across the general line of the Motunau fault. To the north, Cainozoic sedimentary rocks are tightly folded, faulted and intruded by igneous rocks; to the south, the same sediments have gentle, homoclinal dips, except immediately adjacent to the fault, where minor drag may occur, and such faults as occur are mainly small-scale features (Fig. 6). (3) North of the fault tectonic activity has continued through the late Pleistocene as shown by the presence of growing folds at the sea-floor: similar features do not occur to the south.
3
2
I
,O
4
-I.OS !Zway)
Fig. 6. a. 3.5 kHz profile and faulted nature
nature
of the inner shelf just north of the Motunau
of the Cainozoic
sediments
Fault.
Note the complexly
(T). and the presence of pinnacles
of probable
folded intrusive
(p); ignore multiple reflection ( NI).
b. Deep seismic profile essentially Canyon
undeformed is due
sediments,
Extension
Mobile nature
to velocity
72-7 from
the mid-shelf
of the Cainozoic pull-down.)
then by thin Kekenoda
of the Motunau
Group
sediments.
region
south
(Apparent
Basement
(A) is overlain
(reflector
B) and regressive
of the Motunau folding
under
by transparent Gtakou
Fault.
Note the
the head of Pegasus Onekakara
Group
Group.
Fault onshore
Satellite imagery (Fig. 7) shows a marked, east-trending lineation at the mouth of the Waipara River, and we infer this to mark the landward continuation of the Motunau Fault (cf. Wellman, 1979, Fig. 1). As seen offshore, there is an abrupt change of style of deformation across this feature. Cainozoic sequences north of the fault are complexly deformed (Gregg, 1964) with faulting, tight folding and evidence for more than one period of post-Miocene deformation (Bradshaw, 1975; Bradshaw and Newman, 1979), whereas similar sequences to the south are flat-lying or gently dipping, The same contrast in tectonic activity persists to the present, as shown by the presence of high-level marine benches of late Pleistocene age on the north side of the fault at the coast (Wilson, 1963; Suggate et al., 1978). Inland, and a little to the southwest, a further lineation occurs at the junction of the Canterbury Plains and the north Canterbury foothills of the Southern Alps.
141
142
thence
passing
along
River valley (Figs. dextral
fault (Gregg,
occur along mapped
the Kowhai
1964) and Recent
the southern
system
across
Pass and
into the Rakar;l
coincides
with an active
fault traces along the same WSW trend also
orientation
may extend
Porters
Pass this lineation
side of the Rakaia
there, the colinear
the fault
River,
1 and 7). At Porters
River. Though
of the main
deep into
Rakaia
the Southern
Alps.
no faults are presently headwater Since
suggests the other
that more
northerly faults of the Marlborough shear zone show diminishing throw towards the Alpine Fault (Freund, 1971) it is likely that the Motunau Fault too will die out somewhere
in the headwaters
of the Rakaia.
Ancillary faults Just inland from the coast, and along the same eastward trend as the inner shelf sector of the Motunau Fault, occurs the long-known trace of the Ashley Fault, an active, dextral feature (Lensen, 1977) (Figs. 2 and 7). This feature may well continue under the Canterbury Plains and link further west with the main Motunau Fault. Another, but larger, splay from the Motunau Fault probably runs along the inner shelf north of Motunau uplifting rock-platform
Point (Fig. 2) demarcating the seaward edge of an actively that carries only minor modern sediment cover (cf. Fig. 11).
Just south of the Conway Trough this platform northeasterly trending fault which we tentatively Motunau Fault.
is bounded to the east by a major extend southwards to link with the
The Pegasus Bay Fault The Pegasus Bay Fault sequence in central Pegasus
occurs as a substantial dislocation of the Cainozoic Bay, about 20 km south of and subparallel to the main PEGASUS FAULT
0 -
2
4
6
a
Fig. 8. Line interpretation Group
a replacement
IO km
LINE
of deep seismic profile
term for Conway
of the profile is on the right.
Group,
by Warren
-----To
I
72-6
Mobil 72-6. (Nomenclature
preoccupied
BAY
after Carter,
and Speden.
1977: Otakou
1977.) The north end
143
A\\
z
Motunau
Fault
(Figs. 2 and 8). A small anticline
which displaces continues
the sea-floor
onland
northeasterly
under
trending
and is therefore
the Canterbury concentration
occurs
to the south of the fault.
an active feature.
The fault probable
Plains, where it is marked of earthquake
epicentres
by a conspicuous just
northwest
c)f
Christchurch city (Fig. 9). The lack of epicentres further southwest, and the fact thnt the fault is not visible on seismic line BP-A (Fig. 1). suggests that the Pegasus 1Ja~ Fault
is a discrete
feature
rather
than a splay off the Motunau
fault syxtcm.
Seismic activity Summary maps of crustal seismicity (Arabasz and Robinson, 1976; Hatherton. 1980) demonstrate that seismic activity shows a regional change in pattern across the Motunau fault system, and Evison (1971) located the magnitude 7, 1901 Cheviot earthquake near the line of the fault. North and west of the fault seismic activity is similar to that of the main seismic zone of the Hikurangi-Marlborough margins, with frequent earthquakes and earthquake swarms, including deep focus and high intensity (> 6) events (Fig. 9). South of the fault, seismic activity consists of scattered
shallow,
low intensity
earthquakes.
Within
the zone between
the Motunau
and Hope faults, high intensity and deep earthquakes are largely restricted to an area in the northeast, the southern termination of which corresponds to the termination of the Motunau Hikurangi
Trough
fault against
the northerly
trending
faults at the head of the
(Figs. 2 and 9).
Nature and amount of displacement
on the Motunau fault system
The Porters Pass Fault is of dextral structures adjacent to the whole Motunau
strike-slip type, and the style of minor fault system is consistent with it being a
regional dextral feature. No evidence is available regarding the amount of any strike-slip movement on the Motunau Fault. Assuming that the flat-topped plateau to the southeast of the continental slope sector of the fault (profile T4, Fig. 3) represents the downdropped edge of the continental shelf (cf. Kaneko, 1966), and that it was planed at the earliest in the initial glaciations of the late Neogene, a vertical downthrow of c. 500 m to the east has occurred here in the last 3 m.y. But since the fault apparently crosses the shelf further west with little displacement, it seems likely that the throw varies markedly at different places along the fault. Regional significance The change in tectonic style which takes place across the Motunau fault is clearly a regionally significant feature. It has been noted before by, for example, Suggate (1979) but was asserted to occur across the Hope Fault. In fact it is the Motunau fault system which marks the southern boundary of the Marlborough shear belt,
n
and, thereby,
the southern
The discovery feature,
edge of the plate boundary
of the Pegasus Bay Fault,
is also of considerable
zone in eastern
and its identification
significance.
The probable
onland
South island.
as a recently
active
extension
of this
fault lies only a few kilometres northwest of suburban Christchurch, an area currently assigned a grade 2 earthquake risk rating (Clark et al., 1965). This grading may require
reassessment.
The Marlborough zone of strike-slip faulting encompasses the region between the main Alpine (= Wairau) Fault in the north and the Motunau Fault in the south (Fig. 1). Strain
is almost
certainly
not homogeneous
across this 140 km wide zone
(contrast Walcott, 1979, fig. 4), but is rather concentrated in the vicinity of the five major fault systems (cf. Wellman, 1979, fig. 1). However. Walcott (1978) has demonstrated
that
as much
as half of the deformation
may have been
taken
up
within the regions between the major faults. The presence of extensive areas of Cainozoic covering strata without penetrative deformation shows that this strain cannot have been accomplished by ductile flow, at least at higher crustal levels. Thus, we conclude that the regions between the major faults behaved as quasi-elastic blocks or “microplates” during late Cainozoic deformation (cf. the behaviour of the similar Fiordland microplate at the southern end of the Alpine transform-Norris and Carter, 1980). From north to south these blocks are conveniently termed the Spenser, after
Inland
major
Kaikoura,
Seaward
physiographic
features
Kaikoura that
and Conway
they individually
microplates encompass.
respectively, Each
block
contains at least moderately deformed Cainozoic rocks, some occurrences of which are bounded by substantial faults which may have defined even smaller quasi-elastic blocks during deformation (cf. Freund, 1971). Nonetheless, the position of five master fault systems, seems established. THE CONWAY
and consequently
the existence
of four substantial
microplates,
MICROPLATE
The Conway microplate is bounded by the Motunau and Hope fault systems. Within the block there exists a host of smaller faults and folds, arranged in a systematic pattern consistent with dextral transcurrent movement on the bounding master faults (cf. Bishop. 1968: Wilcox et al., 1973). Though our profiler data are insufficient for detailed mapping of offshore structure. we present a composite structural map depicting the major coastal and offshore features (Fig. 2). Growing folds(Figs.
10 and 11)
Most of the continental shelf on the Conway microplate is devoid of modern sediment cover, apart from thin and local patches of biogenic or muddy sediment
pre7c
t
1-1
Stage
I:
125 ky
Tertiary
i 1 I lw5Yl
3%
Fig.
I I. Interpretative
geological
shelf south of the Conway
Trough.
map of the late Quaternary Positions
of profiles
deposits
and shorelines
of the continental
A-D of Figs. 10 and I2 indicated.
offshore, and a narrow band of littoral sand and gravel along the shoreface (Carter et al., 1982). Most of the shelf comprises eroded platforms in either Tertiary sediment or in relict, late Pleistocene sediment wedges (Figs. 10-12). The predominance of erosion over deposition indicates that the shelf is transversed by active bottom currents, and is consistent with active uplift of the microplate with respect to regions further south (cf. Wellman, 1979). Consistent with such an inference, 3.5 kHz profiles reveal the presence of numerous growing folds that affect the late Quaternary, relict sediments on the continental shelf (Figs. 10 and 11). As Lewis (197 1, 1973) has shown for similar folds off Hawkes Bay, successive stages in fold-growth can be inferred from the presence of successively tilted, unconformity-bounded packets of strata on the flanks of the fold. The recent nature of folding, combined with the active uplift and erosion of the shelf, results in a close correlation between folds and bathymetry, with anticlinal
153
154
folds defining young
ridges. In one case the reflecting
fold (Fig.
growing
folds in Hawkes
deep-seated
underthrusting,
the microplate dextral
lo), suggesting
margins,
strike-slip
horizons
the presence
Bay have axes parallel
along the boundary
in the axis of a
pockets
of gas. Whereas
to the continental
those on the Conway su~esting
break-down
of shallow
microplate
they may have been
slope, caused by
have axes oblique
formed
consequent
to
upon
faults (Fig. 2).
The youngest relict sediments of the north Canterbury shelf comprise a series of drowned shoreline wedges, inferred to date from pauses in the rapid transgression after the peak of the last glaciation, i.e. to be between 20 and c. 6 ky old (Carter et al., in prep.).
Unfortunately
these deposits
have been largely eroded
off the Conway
microplate segment of the shelf, making it impossible to confirm that the growing folds affect post-glacial and recent sediment, though such a proposition seems very likely. Most of the microplate is underlain by an earlier, late Quaternary sediment wedge with, in places, older successively tilted Quaternary sediments beneath it. It is most likely that the upper, most widespread
of these earlier late Quaternary
Fig. 11) dates from the last major interglacial, correlation nearby
strengthened
by the existence
i.e. isotope
of warped
deposits
stage 5 at about
terraces
(W3,
125 ky. a
of this probable
age
onland
(Powers, 1962). As the m~imum dip seen on the flanks of folds in rate of tilting of c. 20 micro-degrees,/ky, IV5 is c. 3”, this gives a maximum compatible with that of the growing folds in Hawkes Bay for which Lewis (1971) recorded rates between 2 and 36 micro-degrees/ky. Young faults One 3.5 kHz profile, located just south of the Conway Trough, shows the seaward edge of sedimentary wedge W5 juxtaposed against older Quaternary or Tertiary strata across a fault zone (Fig. 10). The fault has expression on the sea-floor in the form of a gutter up to 10 m deep, confirming
its relatively
young
age.
Tectonic histoy Bradshaw and Newman (1979) have recently described low-angle thrust faults from coastal North Canterbury. They infer that thrusting predated the main phase of faulting and folding, and attribute it to synsedimentary sliding. Probable low-angle thrusting is seen also on a 3.5 kHz profile near the south end of the Conway Ridge (Fig. IO), where it too predates the tilting of the affected sediments. Despite this, and other similar evidence for a multiphase tectonic history, the geometric relations between different structures and the boundary faults of the Conway microplate (Fig. 2) are closely similar to those predicted for trans~urrent tectonic settings (e.g. Wilcox et al., 1973), and found along other major transcurrent faults, such as those of the San Andreas system (e.g. Yeats, 1973). Indeed, a careful
analysis
of secondary
structures
alone would point to the existence
and nature
Motunau fault system, even were no more direct evidence available. We infer that as transcurrent movement proceeded on the Hope faults,
intra-plate
stress was released
plate. Block faults are commonly showing
an irregular
by block
arranged
though broadly
faulting
within
and Motunau
the Conway
at about 60” to the microplate
alternating
pattern
of upthrown
of the
micro-
boundary,
blocks. Throws
of several kilometres are not uncommon, at least on land, where basement Mesozoic metagreywacke is often juxtaposed against the upper formations of the CretaceousCainozoic Kaikoura Sequence (Gregg, 1964). Folding occurred concomitant with block faulting, with anticlinal drape folds located over horsts, and synclines occupying the intervening grabens. Fold axes parallel the NNE trends of the major block faults in the central part of the microplate, but adjacent to the boundary transcurrent faults they swing into positions more nearly parallel to the boundary fault. typically block
making
an angle of 30” or less with the fault (cf. Bishop.
faults are sigmoidal
in shape,
as seen for the Kaiwara
1968). The larger
and Hundalee
faults,
and possibly for the fault bounding the western side of the Conway Trough. which may link with the Hundalee Fault in the north. Though difficult to prove by field evidence,
geometric
considerations
suggest that high-angle
ment on the main part of a sigmoidal on the bent extremities. PLATE-TECTONIC
reverse or normal
block fault will pass into transcurrent
movemotion
SIC;NIFICANCE
Early plate-tectonic interpretations of the Marlborough faults viewed them as secondary transforms which linked the Hikurangi subduction margin with the main Alpine Fault oblique-slip boundary (Wellman, 197 1; Christoffel, 197 1). Following Freund’s (1971) demonstration that individual faults of the Marlborough system have diminishing throws towards the Alpine Fault, and therefore that they may not actually link with the Alpine Fault, Scholz et al. (1973) suggested that the Awatere, Clarence and Hope transform faults have developed sequentially southwards in response to a changing plate motion vector. Later writers have accepted this interpretation. For instance, Arabasz and Robinson (1976) cite seismic data that the descending oceanic lithosphere beneath the Seaward Kaikoura and Conway microplates has only reached depths of c. 100 km and thereby
infer the presence
there of a discrete
segment
of Pacific plate that only
commenced downtuming about 2 m.y. ago. Rynn and Scholz (1978) further support such a model, noting that the abundance of seismic activity south of the Hope Fault suggests that “the Arthurs Pass region is a developing shear zone, since no throughgoing faults have been observed geologically in the region”. These authors further suggest that “the southern boundary of the shear zone is indicated by the model to be about 50 km south of and parallel to the Hope Fault”, which is precisely the location of the Motunau fault system of this paper.
Arabasz
transcurrent
their
citing
history,
fault-angle tion
( 1973) have also argued,
and Robinson
Marlborough
as evidence
depressions.
along
glomerates
along
the thick
Miocene
Such an interpretation
strike-slip
margins
readily
transtensional
Reading,
1980). and
transform
or transduction
parts
setting
is possible,
explain
the
facies evidence
that infill
in
theta
but models of sedimenta-
(Kingma.
for the Marlborough
thr:
block faults earlier
accumulation
of thick
con-
1958; Ballance
and
is in fact consistent
with ;i
region since the inception
of
sedimentation there in the early Miocene (cf. Carter and evidence in support of the southward-propagation model of
Scholz et al. (1973) comes from the fact that the Motunau developed suggesting
( 1963). that
Lensen
conglomerates
of the fault
the sedimentary
tectonically influenced Norris, 1976). Further
after
faults were active solely as normal
fault system is not as well
as a single major dislocation as the more northerly Marlborough faults. its more recent origin. Further south still the Pegasus Bay Fault may have
originated most recently of all. and may develop in Motunau fault system, or else become a microplate Careful sedimentary and stratigraphic studies southward-propagation model further, since the
future into either a splay of the boundary fault in its own right, are clearly needed to test the available regional stratigraphic
evidence (Suggate et al.. 1978) is not suitable for revealing detailed sedimentary trends, or basinal evolution. It is particularly critical to establish the timing of the development of the many small, tectonically controlled basins in the region (cf. Carter et al., 1982). Lewis (1980) has shown that the Hikurangi margin is characterized by underthrust anticlinal ridges, upslope from which develop slope-basins with thick sedimentary basins
fills of hemiterrigenous are now emergent
mudstone in eastern
1980) whilst those on the trench
and
North
redeposited Island
(Van
strata.
The westernmost
der Lingen
slope off the east coast remain
and Pettinga.
active today (Lewis.
1973, 1980). The eastern ends of seismic profiles Mobil 72-3 and Gulfrex 76 show the typical Hikurangi margin style of deformation along an uplifted anticlinal ridge at depths of c. 2000 m on the west wall of the head of the Hikurangi Trough (Figs. 4a and 5). To the west the Conway deep-seated
normal
the Motunau
Trough
faults which, further
strike-slip
and Ridge are apparently
south along the continental
fault. Thus, these profiles
the Benioff zone, at approximately
probably
the foot of the continental
controlled
by
slope, pass into
cross the surface trace of slope east of Conway
Ridge, with underthrusting along the western wall of the head of the Hikurangi Trough passing into dextral transform motion along the Motunau Fault (Fig. 2). Such an interpretation is in accord with regional plate motions (e.g. Walcott. 1978, fig. l), and with the seismic evidence that deep crustal and subcrustal earthquakes are restricted to that portion of the Conway microplate lying north and west of the major bend in the Motunau Fault. Therefore the combined evidence suggests that the Hikurangi Trough remains primarily a subduction feature right to its southern end, where the motion is transferred to the southern margin of the plate boundary zone, presently
marked
by the developing
Motunau
fault system.
Since the pole of
157
rotation
between
southwards
the Indo-Australian
during
the Motunau
and Pacific plates
the late Cainozoic
(Walcott,
has migrated
progressively
1978, fig. l), the rate of strain
fault system should be gradually
increasing
along
with time.
CONCLUSIONS
(1) The southern edge of the plate boundary zone between the Indo-Australian and Pacific plates lies along the Motunau Fault, the southernmost dextral strike-slip fault system of the Marlborough shear zone, and coincides with a marked regional change in seismicity. (2) The Marlborough transform fault system boundary
along
successively
shear linking
the Hikurangi
southwards,
being the most recently (3) Sedimentary
zone developed the oblique-slip
in the early-middle Miocene as a Alpine Fault with the subduction
margin.
of the shear
Faults
with the Motunau
fault
system
zone have developed
and
Pegasus
Bay Fault
formed.
sequences
north
of the Motunau
Fault
are complexly
deformed
compared with those that lie further south outside the plate boundary zone. The change in style of deformation is abrupt and sediments only a few km south of the Motunau fault system are effectively flat-lying, (4) The change in tectonic style from the transcurrent regime of the Marlborough shear zone to the underthrust regime of the Hikurangi subduction zone occurs along the foot of the Marlborough continental slope. The Hikurangi Trough is therefore subduction feature even over its more westerly trending southern portions.
a
ACKNOWLEDGEMENTS
We acknowledge Agreement
the financial
and of the University
support
of the NZ-USA
of Otago research
Scientific
committee.
Co-operation
Ship time on G.R.V.
“Tangaroa” was kindly made available by the New Zealand Oceanographic Institute, and we thank the officers and crew for their support during Cruises 1097 and 1116. The Geophysics Division of the New Zealand D.S.I.R. made available the seismic data plotted as Fig. 9, and we are grateful to Dr. K.F. Priestley for help and advice with this figure. The draft manuscript benefitted from the critical comments of Drs. K.B. Lewis and J.M.W. Rynn, and Bryan Jamieson assisted in the preparation of figures: we thank these colleagues for their advice and help. REFERENCES
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G.J. and Pettinga,
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Sedimentol., Astron.
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R.I.. 1979. Plate motion
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RI. and Cresswell,
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Speden,
1.. 1977. The
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(Mata
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Surv. Bull.. 92: 60 pp. Wellman.
H.W..
Tectonophysics, Wellman,
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Southern Wilcox,
1971. Reference
lines, fault classification,
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12: 199-209. 1979. An uplift map for the South Island of New Zealand,
Alps. Bull. R. Sot. N.Z..
R.E.. Harding.T.P.
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18: 13- 20.
and Seely, D.R.. 1973. Basic wrench
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N.Z. Geol. Surv. Bull.. 64. 122 pp.
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Bull. Am. Assoc.
Pet.
133
88 (1982) 133-159
Elsevier Scientific
Publishing
THE MOTUNAU
Company,
Amsterdam--Printed
FAULT AND OTHER STRUCTURES
EDGE OF THE AUSTRALIAN-PACIFIC MARLBOROUGH,
R.M. CARTER Department
AT THE SOUTHERN
PLATE BOUNDARY,
OFFSHORE
NEW ZEALAND
* and L. CARTER
of Geology, James Cook Universit~y, TownsviNe (Australw)
New Zealand Oceanographic (Received
in The Netherlands
Institute,
P.O. Box 12346, Wellington (New Zealand)
April 13. 1981; revised version
accepted
February
24. 1982)
ABSTRACT
Carter.
R.M. and Carter,
Australian-Pacific The boundary Alpine
Fault.
L., 1982. The Motunau
plate boundary, between
offshore
the Indo-Australian
then links northeastwards
Fault and other structures Marlborough,
at the southern
New Zealand.
and Pacific
with the Hikurangi
plates
passes
subduction
through
margin
transcurrent
faults. The southern
shear zone is situated
a previously
unrecognized
offshore
of the Motunau
Fault,
Porters
Pass Fault
and lineation
(Cretaceous-Cainozoic) formed
data collected evidenced
that underlie
“Tangaroa”
by complexly
by the presence
of deformed
epicentres.
Within
the Marlborough
plate
blocks,
or “microplates”.
20-60
sediments
Inland
Kaikoura.
are most strongly
within each microplate. pattern
being consistent
and geophysical
boundary
causing
right to the southern microplate.
as faults
further
epicentres
Kaikoura
movement
and other
and folding
strata
continue
and Conway
strike-slip
and faulting,
of the Marlborough
Trough.
where the motion
only reach to intermediate
beneath
margin
0040.
University
of Otago,
I95I /X2/0000-0000/$02.75
Dunedin,
to the plate boundary
New Zealand.
i I982 Elaevier Scientific
Publishing
Company
four
Sequence
fault systems; marine
geologic
southwards
durmg
is occurrmg
to the Motunau
t.he southern
developing.
* Formerly
Kaikoura
subduction
is transferred
depths
delimit
to south. these
the overall structural
fault system is not such a continuous
it is likely that this southern
faults
The available
faults. Today,
as
of earthquake
north
blocks respectively.
folding
undegeologtc
of the Motunau
and by the distribution
on the boundary-faults.
Sequence
marine
of the blocks and their subsidiary
to moderate
of the active
in this area today,
of the Pacific plate may have propagated
activation
and since the Motunau
north,
extension
the Kaikoura
shelf are effectively
records
zone the five major
near the margins
head of the Hikurangi
Since earthquake
Conway
successive
limit of the Marlborough
km wide and up to 220 km long. From
is restricted
with dextral
Faulting
late Pleistocene
data suggest that subduction
the late Neogene. system.
deformation
continental
as the
the Marlborough
1097 and 1116 show that the shelf north
sediments.
Seaward
deformed
the Canterbury
zone. 3.5 kHz profiler
Cruises
deformed
substantial
are the Spenser.
To the south
of the plate boundary
on G.R.V.
fault is underlain
system.
sediments
and lie outside
Fault,
New Zealand
through
shear zone. a group of five major, subparallel at the Motunau
edge of the
Tecfonoph.vsics. 88: 133- 159.
physiographic
fault
part of the features
zone is still actively
134
INTRODUCTION
The New Zealand that between connected
Alpine
Fault marks one of the Earth’s major plate boundaries.
the Indo-Australian
to the Hikurangi
and Pacific plates.
Trough
subduction
The north
complex
end of the fault is
by the Marlborough
shear
zone, comprising several large dextral faults splaying northeast from the main Alpine-Wairau Fault (Fig. 1). Walcott has shown from geodetic data that the major faults of the Marlborough shear zone only accommodate about half of the observed modem strain, and that “at least half the movement.. . may be made up of displacements
on numerous
minor
faults, rotation
ductile flow in the crust” (Walcott, Within the terms of plate-tectonic
MOBIL
GULFREX
of blocks between
1978, p. 153). models, the Alpine
the major faults or by
Fault is considered
today as
1972
1973
42’
Fig. 1. Regional bathymetric
locality
profiles
as in the original
map for northeastern
available
track charts:
South
Island
for the Canterbury-Marlborough an uncertainty
of position
showing
the positions
shelr. (Oil-company
of al least
of the seismic profiles
e 2 km is possible.)
and
are plotted
135
a trench-trench major
Hikurangi seismic,
transform
element
(McKenzie
of compression
Trough,
a filled trench
sedimentologic
and
and Morgan,
developed (Katz,
structural
(Scholz
1969), along which
et al., 1973; Lensen,
1974) is situated features
there is a 1975). The
just east of the volcanic,
of the North
Island
subduction
complex (Cole, 1978; Hatherton, 1980; Lewis, 1973, 1980). The Marlborough shear zone between is less well understood. Though most writers agree that the Marlborough faults are dominantly strike-slip, opinion is divided as to how the faults were initiated, and as to whether all faults of the system are equally active or whether they have developed sequentially to the south in response to changing plate motions (Scholz et al., 1973). The precise way in which subduction changes
to dominantly
strike-slip
motion
on the Hikurangi
in the Marlborough
shear
under
discussion;
Arabasz
and Robinson
(1976) show that deep crustal
define
a dipping
Benioff
zone
the more
Fig. 2. Structural
map of the north
data
(1964).
from Gregg
beneath
Canberburlv-hlarlborough
northerly
faults
shelf and adjacent
margin
zone is also earthquakes
of the system,
areas onland.
Onland
136
whereas
Lewis (1980)
argues
that the southern
west of where it swings in towards
portion
the Marlborough
of the Hikurangi coast, is largely
Trough.
a transform
feature. The southern boundary
1979; Sporli, and
margin
of the Marlborough
zone, has traditionally 1980). G.R.V.
1116 (December,
the continental
“Tangaroa”
1980) included
the shelf in this region, uplifted.
Deformation
of the Hope Fault.
to the
1979)
and sampling
These data,
together
profiles (e.g. Mobil, shear zone continues
by growing
abruptly
of the plate (e.g. Suggate.
1097 (August-September,
of seismic profiling
petroleum company with the Marlborough
which is underlain terminates
with the Hope Fault
Cruises
periods
shelf to the southeast
unpublished but freely available show that deformation associated
shear zone, and therefore
been identified
on with
1972), across
folds and is being actively
southeast
along
a previously
unmapped, major fault of the Marlborough shear zone, the Motunau fault system (Fig. 2). We take the opportunity here to describe this feature and its associated structures,
and to comment
THE MOTUNAU
FAULT
on the regional
significance
of these new data.
SYSTEM
The Motunau Fault occurs as a major bathymetric feature crossing the continental slope about half way between Banks and Kaikoura peninsulas (Figs. 2-3). Near latitude 43”s the fault trends NE and is marked by a narrow gutter, up to 200 m deep, separating a flat-topped spur from the upper parts of the continental slope, themselves steep and continuous with the western wall of the gutter (Fig. 3, Line T4). At its eastern end the fault passes into north-trending faults that extend along the continental slope to define the eastern side of Conway Ridge. The infrequency of suitable satellite passes over New Zealand means that there is considerable uncertainty in the location of the available deep seismic lines in this vicinity (? c. 2 km). Nonetheless, we infer that profiles Mobile 72-4 (Fig. 4) and Gulfrex
76 (Fig. 5) cross the Motunau
Fault.
The continental dipping sequence
shelf and upper slope (Figs. 4-5) are underlain by an eastward of Cretaceous-Cainozoic rocks which can be divided into two
seismic sequences
across a mid-Cainozoic
unconformity.
Below the unconformity
lie
complexly folded and faulted strata of the Onekakara Group (Carter, 1977), a marine transgressive sequence that developed across eastern South Island between the Late Cretaceous and Oligocene. Above the unconformity lie less deformed, but still folded and faulted, strata equivalent to the Otakou Group, which represents the eastward propagation of the eastern South Island late Cainozoic continental shelfslope complex, a regressive sedimentary sequence which formed consequent upon uplift along the plate boundary zone further west (e.g. Walcott and Cresswell, 1979). By analogy with nearby onland sequences (e.g. Prebble, 1980) the unconformity is probably of early middle Miocene age, and marks the start of tectonically controlled sedimentation associated with the development of the Mariborough shear zone (Carter and Norris, 1976).
137
‘. Kai koura
Motunau Fault
Fig. 3. Bathymetric
profiles
across
the continental
margin
betwern
the Conway
and Hurunui
Kl~ers iwc
Fig. 1 for location).
This bipartite
sedimentary
sequence
is truncated
to the east by a deep-seated
and
active fault which displaces the sea-floor by about 200 m, and is associated with a number of smaller, shallow faults further east still. The sedimentary sequence to the east of the ~otunau Fault comprises gently deformed sediments with entirely different reflection characteristics to those west of the fault, their regularly reflecting nature suggesting they form part of the late Cainozoic Trough (cf. Katz, 1974; Lewis, 1980).
turbiditic
fill of the Hikurangi
Fig. 4. Line interpretatians
of deep seismic profiles
Mobil 72-3 and 72-4
0
(a) LINE
5
72 -3
10 15 km
5s
4s
33
2s
15
OS
139
20 km
10
Fig. 5. The Motunau
Extension
Fault as seen on deep seismic profile Gulfrex
76. (Ignore
multiple
reflection,
WI)
landwards across the shelf
South of latitude 43’S the Motunau Fault bends rapidly and traverses continental shelf in a more nearly easterly direction. Few deep seismic profiles
the are
available from this region (Fig. l), making it difficult to specify the exact location of the fault. However, the Motunau Fault is inferred to run up the sea-valley seen on line T4 (Figs. 1, 3) and to continue westwards to link with faults on the same trend on the inner shelf (Fig. 2). (An alternative interpretation would be that the inner shelf and slope features Despite
represent
discrete
but broadly
the lack of deep seismic cover, a number
which cross the projected lines cover the region following facts:
extension
cohnear
faults.)
of 3.5 kHz profiles
are available
of the fault across shelf, and a number
to the northwest
of the fault. These profiles
of other
demonstrate
the
(1) The shelf sector of the Motunau fault does not involve appreciable displacement of the sea-floor, at least by comparison with that seen on the continental slope. (2) A dramatic change in tectonic style takes place across the general line of the Motunau fault. To the north, Cainozoic sedimentary rocks are tightly folded, faulted and intruded by igneous rocks; to the south, the same sediments have gentle, homoclinal dips, except immediately adjacent to the fault, where minor drag may occur, and such faults as occur are mainly small-scale features (Fig. 6). (3) North of the fault tectonic activity has continued through the late Pleistocene as shown by the presence of growing folds at the sea-floor: similar features do not occur to the south.
3
2
I
,O
4
-I.OS !Zway)
Fig. 6. a. 3.5 kHz profile and faulted nature
nature
of the inner shelf just north of the Motunau
of the Cainozoic
sediments
Fault.
Note the complexly
(T). and the presence of pinnacles
of probable
folded intrusive
(p); ignore multiple reflection ( NI).
b. Deep seismic profile essentially Canyon
undeformed is due
sediments,
Extension
Mobile nature
to velocity
72-7 from
the mid-shelf
of the Cainozoic pull-down.)
then by thin Kekenoda
of the Motunau
Group
sediments.
region
south
(Apparent
Basement
(A) is overlain
(reflector
B) and regressive
of the Motunau folding
under
by transparent Gtakou
Fault.
Note the
the head of Pegasus Onekakara
Group
Group.
Fault onshore
Satellite imagery (Fig. 7) shows a marked, east-trending lineation at the mouth of the Waipara River, and we infer this to mark the landward continuation of the Motunau Fault (cf. Wellman, 1979, Fig. 1). As seen offshore, there is an abrupt change of style of deformation across this feature. Cainozoic sequences north of the fault are complexly deformed (Gregg, 1964) with faulting, tight folding and evidence for more than one period of post-Miocene deformation (Bradshaw, 1975; Bradshaw and Newman, 1979), whereas similar sequences to the south are flat-lying or gently dipping, The same contrast in tectonic activity persists to the present, as shown by the presence of high-level marine benches of late Pleistocene age on the north side of the fault at the coast (Wilson, 1963; Suggate et al., 1978). Inland, and a little to the southwest, a further lineation occurs at the junction of the Canterbury Plains and the north Canterbury foothills of the Southern Alps.
141
142
thence
passing
along
River valley (Figs. dextral
fault (Gregg,
occur along mapped
the Kowhai
1964) and Recent
the southern
system
across
Pass and
into the Rakar;l
coincides
with an active
fault traces along the same WSW trend also
orientation
may extend
Porters
Pass this lineation
side of the Rakaia
there, the colinear
the fault
River,
1 and 7). At Porters
River. Though
of the main
deep into
Rakaia
the Southern
Alps.
no faults are presently headwater Since
suggests the other
that more
northerly faults of the Marlborough shear zone show diminishing throw towards the Alpine Fault (Freund, 1971) it is likely that the Motunau Fault too will die out somewhere
in the headwaters
of the Rakaia.
Ancillary faults Just inland from the coast, and along the same eastward trend as the inner shelf sector of the Motunau Fault, occurs the long-known trace of the Ashley Fault, an active, dextral feature (Lensen, 1977) (Figs. 2 and 7). This feature may well continue under the Canterbury Plains and link further west with the main Motunau Fault. Another, but larger, splay from the Motunau Fault probably runs along the inner shelf north of Motunau uplifting rock-platform
Point (Fig. 2) demarcating the seaward edge of an actively that carries only minor modern sediment cover (cf. Fig. 11).
Just south of the Conway Trough this platform northeasterly trending fault which we tentatively Motunau Fault.
is bounded to the east by a major extend southwards to link with the
The Pegasus Bay Fault The Pegasus Bay Fault sequence in central Pegasus
occurs as a substantial dislocation of the Cainozoic Bay, about 20 km south of and subparallel to the main PEGASUS FAULT
0 -
2
4
6
a
Fig. 8. Line interpretation Group
a replacement
IO km
LINE
of deep seismic profile
term for Conway
of the profile is on the right.
Group,
by Warren
-----To
I
72-6
Mobil 72-6. (Nomenclature
preoccupied
BAY
after Carter,
and Speden.
1977: Otakou
1977.) The north end
143
A\\
z
Motunau
Fault
(Figs. 2 and 8). A small anticline
which displaces continues
the sea-floor
onland
northeasterly
under
trending
and is therefore
the Canterbury concentration
occurs
to the south of the fault.
an active feature.
The fault probable
Plains, where it is marked of earthquake
epicentres
by a conspicuous just
northwest
c)f
Christchurch city (Fig. 9). The lack of epicentres further southwest, and the fact thnt the fault is not visible on seismic line BP-A (Fig. 1). suggests that the Pegasus 1Ja~ Fault
is a discrete
feature
rather
than a splay off the Motunau
fault syxtcm.
Seismic activity Summary maps of crustal seismicity (Arabasz and Robinson, 1976; Hatherton. 1980) demonstrate that seismic activity shows a regional change in pattern across the Motunau fault system, and Evison (1971) located the magnitude 7, 1901 Cheviot earthquake near the line of the fault. North and west of the fault seismic activity is similar to that of the main seismic zone of the Hikurangi-Marlborough margins, with frequent earthquakes and earthquake swarms, including deep focus and high intensity (> 6) events (Fig. 9). South of the fault, seismic activity consists of scattered
shallow,
low intensity
earthquakes.
Within
the zone between
the Motunau
and Hope faults, high intensity and deep earthquakes are largely restricted to an area in the northeast, the southern termination of which corresponds to the termination of the Motunau Hikurangi
Trough
fault against
the northerly
trending
faults at the head of the
(Figs. 2 and 9).
Nature and amount of displacement
on the Motunau fault system
The Porters Pass Fault is of dextral structures adjacent to the whole Motunau
strike-slip type, and the style of minor fault system is consistent with it being a
regional dextral feature. No evidence is available regarding the amount of any strike-slip movement on the Motunau Fault. Assuming that the flat-topped plateau to the southeast of the continental slope sector of the fault (profile T4, Fig. 3) represents the downdropped edge of the continental shelf (cf. Kaneko, 1966), and that it was planed at the earliest in the initial glaciations of the late Neogene, a vertical downthrow of c. 500 m to the east has occurred here in the last 3 m.y. But since the fault apparently crosses the shelf further west with little displacement, it seems likely that the throw varies markedly at different places along the fault. Regional significance The change in tectonic style which takes place across the Motunau fault is clearly a regionally significant feature. It has been noted before by, for example, Suggate (1979) but was asserted to occur across the Hope Fault. In fact it is the Motunau fault system which marks the southern boundary of the Marlborough shear belt,
n
and, thereby,
the southern
The discovery feature,
edge of the plate boundary
of the Pegasus Bay Fault,
is also of considerable
zone in eastern
and its identification
significance.
The probable
onland
South island.
as a recently
active
extension
of this
fault lies only a few kilometres northwest of suburban Christchurch, an area currently assigned a grade 2 earthquake risk rating (Clark et al., 1965). This grading may require
reassessment.
The Marlborough zone of strike-slip faulting encompasses the region between the main Alpine (= Wairau) Fault in the north and the Motunau Fault in the south (Fig. 1). Strain
is almost
certainly
not homogeneous
across this 140 km wide zone
(contrast Walcott, 1979, fig. 4), but is rather concentrated in the vicinity of the five major fault systems (cf. Wellman, 1979, fig. 1). However. Walcott (1978) has demonstrated
that
as much
as half of the deformation
may have been
taken
up
within the regions between the major faults. The presence of extensive areas of Cainozoic covering strata without penetrative deformation shows that this strain cannot have been accomplished by ductile flow, at least at higher crustal levels. Thus, we conclude that the regions between the major faults behaved as quasi-elastic blocks or “microplates” during late Cainozoic deformation (cf. the behaviour of the similar Fiordland microplate at the southern end of the Alpine transform-Norris and Carter, 1980). From north to south these blocks are conveniently termed the Spenser, after
Inland
major
Kaikoura,
Seaward
physiographic
features
Kaikoura that
and Conway
they individually
microplates encompass.
respectively, Each
block
contains at least moderately deformed Cainozoic rocks, some occurrences of which are bounded by substantial faults which may have defined even smaller quasi-elastic blocks during deformation (cf. Freund, 1971). Nonetheless, the position of five master fault systems, seems established. THE CONWAY
and consequently
the existence
of four substantial
microplates,
MICROPLATE
The Conway microplate is bounded by the Motunau and Hope fault systems. Within the block there exists a host of smaller faults and folds, arranged in a systematic pattern consistent with dextral transcurrent movement on the bounding master faults (cf. Bishop. 1968: Wilcox et al., 1973). Though our profiler data are insufficient for detailed mapping of offshore structure. we present a composite structural map depicting the major coastal and offshore features (Fig. 2). Growing folds(Figs.
10 and 11)
Most of the continental shelf on the Conway microplate is devoid of modern sediment cover, apart from thin and local patches of biogenic or muddy sediment
pre7c
t
1-1
Stage
I:
125 ky
Tertiary
i 1 I lw5Yl
3%
Fig.
I I. Interpretative
geological
shelf south of the Conway
Trough.
map of the late Quaternary Positions
of profiles
deposits
and shorelines
of the continental
A-D of Figs. 10 and I2 indicated.
offshore, and a narrow band of littoral sand and gravel along the shoreface (Carter et al., 1982). Most of the shelf comprises eroded platforms in either Tertiary sediment or in relict, late Pleistocene sediment wedges (Figs. 10-12). The predominance of erosion over deposition indicates that the shelf is transversed by active bottom currents, and is consistent with active uplift of the microplate with respect to regions further south (cf. Wellman, 1979). Consistent with such an inference, 3.5 kHz profiles reveal the presence of numerous growing folds that affect the late Quaternary, relict sediments on the continental shelf (Figs. 10 and 11). As Lewis (197 1, 1973) has shown for similar folds off Hawkes Bay, successive stages in fold-growth can be inferred from the presence of successively tilted, unconformity-bounded packets of strata on the flanks of the fold. The recent nature of folding, combined with the active uplift and erosion of the shelf, results in a close correlation between folds and bathymetry, with anticlinal
153
154
folds defining young
ridges. In one case the reflecting
fold (Fig.
growing
folds in Hawkes
deep-seated
underthrusting,
the microplate dextral
lo), suggesting
margins,
strike-slip
horizons
the presence
Bay have axes parallel
along the boundary
in the axis of a
pockets
of gas. Whereas
to the continental
those on the Conway su~esting
break-down
of shallow
microplate
they may have been
slope, caused by
have axes oblique
formed
consequent
to
upon
faults (Fig. 2).
The youngest relict sediments of the north Canterbury shelf comprise a series of drowned shoreline wedges, inferred to date from pauses in the rapid transgression after the peak of the last glaciation, i.e. to be between 20 and c. 6 ky old (Carter et al., in prep.).
Unfortunately
these deposits
have been largely eroded
off the Conway
microplate segment of the shelf, making it impossible to confirm that the growing folds affect post-glacial and recent sediment, though such a proposition seems very likely. Most of the microplate is underlain by an earlier, late Quaternary sediment wedge with, in places, older successively tilted Quaternary sediments beneath it. It is most likely that the upper, most widespread
of these earlier late Quaternary
Fig. 11) dates from the last major interglacial, correlation nearby
strengthened
by the existence
i.e. isotope
of warped
deposits
stage 5 at about
terraces
(W3,
125 ky. a
of this probable
age
onland
(Powers, 1962). As the m~imum dip seen on the flanks of folds in rate of tilting of c. 20 micro-degrees,/ky, IV5 is c. 3”, this gives a maximum compatible with that of the growing folds in Hawkes Bay for which Lewis (1971) recorded rates between 2 and 36 micro-degrees/ky. Young faults One 3.5 kHz profile, located just south of the Conway Trough, shows the seaward edge of sedimentary wedge W5 juxtaposed against older Quaternary or Tertiary strata across a fault zone (Fig. 10). The fault has expression on the sea-floor in the form of a gutter up to 10 m deep, confirming
its relatively
young
age.
Tectonic histoy Bradshaw and Newman (1979) have recently described low-angle thrust faults from coastal North Canterbury. They infer that thrusting predated the main phase of faulting and folding, and attribute it to synsedimentary sliding. Probable low-angle thrusting is seen also on a 3.5 kHz profile near the south end of the Conway Ridge (Fig. IO), where it too predates the tilting of the affected sediments. Despite this, and other similar evidence for a multiphase tectonic history, the geometric relations between different structures and the boundary faults of the Conway microplate (Fig. 2) are closely similar to those predicted for trans~urrent tectonic settings (e.g. Wilcox et al., 1973), and found along other major transcurrent faults, such as those of the San Andreas system (e.g. Yeats, 1973). Indeed, a careful
analysis
of secondary
structures
alone would point to the existence
and nature
Motunau fault system, even were no more direct evidence available. We infer that as transcurrent movement proceeded on the Hope faults,
intra-plate
stress was released
plate. Block faults are commonly showing
an irregular
by block
arranged
though broadly
faulting
within
and Motunau
the Conway
at about 60” to the microplate
alternating
pattern
of upthrown
of the
micro-
boundary,
blocks. Throws
of several kilometres are not uncommon, at least on land, where basement Mesozoic metagreywacke is often juxtaposed against the upper formations of the CretaceousCainozoic Kaikoura Sequence (Gregg, 1964). Folding occurred concomitant with block faulting, with anticlinal drape folds located over horsts, and synclines occupying the intervening grabens. Fold axes parallel the NNE trends of the major block faults in the central part of the microplate, but adjacent to the boundary transcurrent faults they swing into positions more nearly parallel to the boundary fault. typically block
making
an angle of 30” or less with the fault (cf. Bishop.
faults are sigmoidal
in shape,
as seen for the Kaiwara
1968). The larger
and Hundalee
faults,
and possibly for the fault bounding the western side of the Conway Trough. which may link with the Hundalee Fault in the north. Though difficult to prove by field evidence,
geometric
considerations
suggest that high-angle
ment on the main part of a sigmoidal on the bent extremities. PLATE-TECTONIC
reverse or normal
block fault will pass into transcurrent
movemotion
SIC;NIFICANCE
Early plate-tectonic interpretations of the Marlborough faults viewed them as secondary transforms which linked the Hikurangi subduction margin with the main Alpine Fault oblique-slip boundary (Wellman, 197 1; Christoffel, 197 1). Following Freund’s (1971) demonstration that individual faults of the Marlborough system have diminishing throws towards the Alpine Fault, and therefore that they may not actually link with the Alpine Fault, Scholz et al. (1973) suggested that the Awatere, Clarence and Hope transform faults have developed sequentially southwards in response to a changing plate motion vector. Later writers have accepted this interpretation. For instance, Arabasz and Robinson (1976) cite seismic data that the descending oceanic lithosphere beneath the Seaward Kaikoura and Conway microplates has only reached depths of c. 100 km and thereby
infer the presence
there of a discrete
segment
of Pacific plate that only
commenced downtuming about 2 m.y. ago. Rynn and Scholz (1978) further support such a model, noting that the abundance of seismic activity south of the Hope Fault suggests that “the Arthurs Pass region is a developing shear zone, since no throughgoing faults have been observed geologically in the region”. These authors further suggest that “the southern boundary of the shear zone is indicated by the model to be about 50 km south of and parallel to the Hope Fault”, which is precisely the location of the Motunau fault system of this paper.
Arabasz
transcurrent
their
citing
history,
fault-angle tion
( 1973) have also argued,
and Robinson
Marlborough
as evidence
depressions.
along
glomerates
along
the thick
Miocene
Such an interpretation
strike-slip
margins
readily
transtensional
Reading,
1980). and
transform
or transduction
parts
setting
is possible,
explain
the
facies evidence
that infill
in
theta
but models of sedimenta-
(Kingma.
for the Marlborough
thr:
block faults earlier
accumulation
of thick
con-
1958; Ballance
and
is in fact consistent
with ;i
region since the inception
of
sedimentation there in the early Miocene (cf. Carter and evidence in support of the southward-propagation model of
Scholz et al. (1973) comes from the fact that the Motunau developed suggesting
( 1963). that
Lensen
conglomerates
of the fault
the sedimentary
tectonically influenced Norris, 1976). Further
after
faults were active solely as normal
fault system is not as well
as a single major dislocation as the more northerly Marlborough faults. its more recent origin. Further south still the Pegasus Bay Fault may have
originated most recently of all. and may develop in Motunau fault system, or else become a microplate Careful sedimentary and stratigraphic studies southward-propagation model further, since the
future into either a splay of the boundary fault in its own right, are clearly needed to test the available regional stratigraphic
evidence (Suggate et al.. 1978) is not suitable for revealing detailed sedimentary trends, or basinal evolution. It is particularly critical to establish the timing of the development of the many small, tectonically controlled basins in the region (cf. Carter et al., 1982). Lewis (1980) has shown that the Hikurangi margin is characterized by underthrust anticlinal ridges, upslope from which develop slope-basins with thick sedimentary basins
fills of hemiterrigenous are now emergent
mudstone in eastern
1980) whilst those on the trench
and
North
redeposited Island
(Van
strata.
The westernmost
der Lingen
slope off the east coast remain
and Pettinga.
active today (Lewis.
1973, 1980). The eastern ends of seismic profiles Mobil 72-3 and Gulfrex 76 show the typical Hikurangi margin style of deformation along an uplifted anticlinal ridge at depths of c. 2000 m on the west wall of the head of the Hikurangi Trough (Figs. 4a and 5). To the west the Conway deep-seated
normal
the Motunau
Trough
faults which, further
strike-slip
and Ridge are apparently
south along the continental
fault. Thus, these profiles
the Benioff zone, at approximately
probably
the foot of the continental
controlled
by
slope, pass into
cross the surface trace of slope east of Conway
Ridge, with underthrusting along the western wall of the head of the Hikurangi Trough passing into dextral transform motion along the Motunau Fault (Fig. 2). Such an interpretation is in accord with regional plate motions (e.g. Walcott. 1978, fig. l), and with the seismic evidence that deep crustal and subcrustal earthquakes are restricted to that portion of the Conway microplate lying north and west of the major bend in the Motunau Fault. Therefore the combined evidence suggests that the Hikurangi Trough remains primarily a subduction feature right to its southern end, where the motion is transferred to the southern margin of the plate boundary zone, presently
marked
by the developing
Motunau
fault system.
Since the pole of
157
rotation
between
southwards
the Indo-Australian
during
the Motunau
and Pacific plates
the late Cainozoic
(Walcott,
has migrated
progressively
1978, fig. l), the rate of strain
fault system should be gradually
increasing
along
with time.
CONCLUSIONS
(1) The southern edge of the plate boundary zone between the Indo-Australian and Pacific plates lies along the Motunau Fault, the southernmost dextral strike-slip fault system of the Marlborough shear zone, and coincides with a marked regional change in seismicity. (2) The Marlborough transform fault system boundary
along
successively
shear linking
the Hikurangi
southwards,
being the most recently (3) Sedimentary
zone developed the oblique-slip
in the early-middle Miocene as a Alpine Fault with the subduction
margin.
of the shear
Faults
with the Motunau
fault
system
zone have developed
and
Pegasus
Bay Fault
formed.
sequences
north
of the Motunau
Fault
are complexly
deformed
compared with those that lie further south outside the plate boundary zone. The change in style of deformation is abrupt and sediments only a few km south of the Motunau fault system are effectively flat-lying, (4) The change in tectonic style from the transcurrent regime of the Marlborough shear zone to the underthrust regime of the Hikurangi subduction zone occurs along the foot of the Marlborough continental slope. The Hikurangi Trough is therefore subduction feature even over its more westerly trending southern portions.
a
ACKNOWLEDGEMENTS
We acknowledge Agreement
the financial
and of the University
support
of the NZ-USA
of Otago research
Scientific
committee.
Co-operation
Ship time on G.R.V.
“Tangaroa” was kindly made available by the New Zealand Oceanographic Institute, and we thank the officers and crew for their support during Cruises 1097 and 1116. The Geophysics Division of the New Zealand D.S.I.R. made available the seismic data plotted as Fig. 9, and we are grateful to Dr. K.F. Priestley for help and advice with this figure. The draft manuscript benefitted from the critical comments of Drs. K.B. Lewis and J.M.W. Rynn, and Bryan Jamieson assisted in the preparation of figures: we thank these colleagues for their advice and help. REFERENCES
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