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The structure and tectonics of the intraplate deformation area in the Indian Ocean
Tectonophysics, 156 (1988) 89-106 Elsevier Science Publishers
The structure
YURI
89
B.V.. Amsterdam
- Printed
in The Netherlands
and tectonics of the intraplate in the Indian Ocean
P. NEPROCHNOV,
OLEG
V. LEVCHENKO,
and VLADIMIR
deformation
LEV
area
R. MERKLIN
V. SEDOV
P.P. Shirshov Institute of Oceanology, Moscow 117218 (U.S.S.R.) (Received
February
2, 1987; revised version accepted
April 6, 1988)
Abstract Neprochnov,
Y.P., Levchenko,
deformation Intense
tectonic
formed
of sediments
reflection
by the P.P. Shirshov
NE-trending
area
profiles
Institute
of crustal
and basement
from
unusual
the northern
of Oceanology
of these deformations.
by a mosaic
L.R. and Sedov, V.V., 1988. The structure
and tectonics
of the intraplate
Tectonophysics, 156:89-106
Ocean.
deformations
can be seen on seismic collected
O.V., Merklin,
area in the Indian
for the interior
Central
Indian
of the USSR
The intraplate
Academy
deformation
area
blocks which have been severely deformed
of the oceanic
Basin.
lithosphere
plates
lO,OOO-mile long CSP profiles
of Sciences
allow
has a complicated
or tilted alternating
delineation
tectonic
of a
framework,
with less deformed
parts
of the sea floor. The results of a detailed two genetic indicate Ocean
types:
an anomalous Bottom
CSP grid survey reveal that these uplifted
old nearly
meridional
structure
Seismographs
fracture
of the crust
have proved
zones, and young
and upper
mantle
faulted
within
that there is high-level
blocks are bounded
NE-striking
faults.
these blocks.
intraplate
by tectonic
Seismological
seismicity
faults of
The seismic refraction
results
observations
in the northern
from
Central
Indian
Basin. The intraplate
deformation
area is supposed
to correspond
result of the stress difference
in the Indo-Australian
Asia
in the Central
along
continental
with
part continuously plate, NE-SW the sediments the system near-latitudinal deformation
spreading
collision
led to an increase
subducted trending
beneath
shearing
and basement, of ancient scarps
failures
spreading
and
normal
In the complicated
on seismic reflection
in the
zone of shearing collision
subduction
stress in the northernmost
apparently
to the mid-oceanic
area might be partly
Ridge
the Sunda Trench.
observed
parallel
Indian
in compressional
stress abated,
to a large-scale
plate due to the continued
oceanic ridge
profiles. crust
NE-SW
in the Sunda
as a
of India and
Island
zone between
Arc.
This
these parts of the
as a result of folding
trending
(near-meridional
axis). The mosaic
that formed
part of the plate, while its southern
transitional
in the Late Miocene,
strains
of the continents
fault-fold
wrench-fault transform
and faulting
tectonics
faults
framework
and,
of
affected perhaps,
of the intraplate
a result of this interaction.
Introduction
are normally recorded only at their boundaries, while the Central Indian Basin is located within
High present-day seismicity, abnormally high heat flow, intense tectonic deformations of sediments and basement, as well as other unusual geophysical characteristics (see e.g., Weissel et al., 1980) make the Central Indian Basin unique among oceanic basins. These phenomena are not typical of the interiors of lithospheric plates and
the one-piece Indo-Australian plate (see, e.g., Sclater and Fisher, 1974; Zonenshain and Savostin, 1979). These seemingly contradictory facts aronsed our interest in the area. Until recently, the tectonic aspects of the peculiarity of the Central Indian Basin were mainly based on studies of the high intraplate seismicity.
004O-1951/88/$03.50
0 1988 Elsevier
Science Publishers
B.V.
90
Sykes (1970) proposed a convergent plate boundary and a nascent island arc between Sri Lanka and the Cocos Islands. Later, a boundary consisting of left-lateral strike-slip motion between the Indian and Australian plates along the
northern Ninetyeast Ridge was suggested (Stein and Okal, 1978). At present, there are more than ten different explanations of the nature of the largest free-air gravity low and the most prominent low of the total gravimetric geoid in the
/ \ 2c I
-
i \
1cI-
c)-
/
/ 1c)-‘
< .~ 1
./ ‘
2c I-
I,/\ ,_ 70
80
Fig. 1. Continuous single-channel
J
90
1Of3
seismic reflection profiles carried out by the P.P. Shirshov Institute of Oceanology of the USSR
Academy of Sciences in the Eastern Indian Ocean. I = profiles and detailed survey areas of R/V “Dmitry (heavy lines AA’ and BB’
show the location of the profiles from Fig. 4); 2 = the same for 1976-1981 4 = isobaths in km.
Mendeleev” cruise 31
cruises;
3 = DSDP
sites;
91
Indian
Ocean south of Sri Lanka (Chekunov
1984)
none
accepted.
of
which
The mechanism
heat flow recorded spheric
seems
to
be
and source
generally
of the high
there, which is related
deformation,
to litho-
unclear
(Geller
et al., 1983). This paper deals with intense
tectonic
deformation
of sediments
are pronounced which
also remain
et al.,
and
basement,
on seismic reflection
are the most conspicuous
which
profiles
anomalous
and phe-
nomena. The mid-plate
deformation
of sediments
and
basement in the Central Indian Basin were first reported by Eittreim and Ewing (1972) who suggested that their existence was the result creasing compressional stress in the interior
of inof the
Indo-Australian plate due to the collision between the Indian subcontinent and Asia. That hypothesis still holds true. The beginning of these deformations is believed to be connected with the Miocene Himalayan erogenic phase of this collision (Weisse1 et al., 1980). The first investigations of the intraplate deformations in the Central Indian Basin were carried out by Soviet scientists of the P.P. Shirshov Institute of Oceanology in 1976 on the R/V “Vityaz” cruise 58 (Neprochnov et al., 1979) and continued in 1980 on the R/V ‘Dmitry Mendeleev” cruise 25 and in 1981 on the R/V “Academician Kurchatov” cruise 32 (Levchenko et al., 1985). In 1984 on the R/V “Dmitry Mendeleev” cruise 31, investigations connected with these intraplate deformations out, including two highly detailed physical
were carried geological-geo-
surveys in the areas shown in Fig. 1. New
important data on the structure and seismicity of the region were obtained. We hope that the seismic reflection profiling data collected during our cruises and recent research into the tectonic framework of the intraplate deformation area will throw some light on the problem Results of continuous
of its genesis.
seismic profiling of the re-
(Weissel
et al., 1980)
to delineate
the unique
there (Levchenko (azimuth
900-1000
and
deformation
62-75”)
1600
km
are located
between
1’s
4 o N and 4 o S of the western
eastern
(near
long
and
to 89“ E (Fig. and
9’S
and
(near 76 o E)
89” E) sides of the delineated
intraplate
deformation
framework
of this area is inhomogeneous
characterized
area
were traced in a NE-trending
km wide from 77”30’E
2). They between
intraplate
et al., 1985).
The deformations band
they have made it possible
area
by extremely
respectively.
deformed
The and is
crustal blocks
that are conspicuous against the weaker and more monotonous deformations of sediments and basement.
About
15 of these large tectonized
blocks,
which are either symmetrically upwarped (Fig. 3) or asymmetrically tilted (Fig. 4), have been identified up to now. They appear in the cross section as gently sloping anticlinal basement rises from 50 to 200-300 km wide and l-2 km high, corresponding conformably to sea-floor swells from 100 to 600 m high. On the rises, the l-2 km thick sediment cover is crumpled into asymmetric folds (mostly with high-angle sloping southern limbs) up to several hundred meters high. The sediments and basement between the tectonized fault blocks are less deformed and are unconformably by the undisturbed sediments, 100-400 which form the flat basin’s
bottom.
overlaid m thick,
In the north-
ern part of the area, some of the fault blocks totally buried km thick.
under
flat-lying
sediments
are
up to 0.8
Four regional seismic reflection profiles obtained on the R/V “Dmitry Mendeleev” cruise 31 have supplemented the grid of profiles covering the intraplate deformation area in the Central Indian Basin (Fig. 1). The appearance of the fault-fold deformations on these profiles coincides with the predicted boundaries intraplate deformation area
of the identified (Fig. 2) but the
gion
seismic reflection records reveal that there is a great variety in the fault blocks and that the area
The seismic reflection data we collected during the 1976-1981 cruises have given us a clear picture of the morphology of the deformations in sediments and basement in the Central Indian Basin. Together with the published American data
has a more complex tectonic framework than we believed earlier (Levchenko et al., 1985). Two large tilted fault blocks, 100 and 200 km long, were traversed with seismic reflection profiles near 2.5”S, 81” E and 1” N, 83”E respectively (Fig. 4). In contrast to most of the folds already studied,
92
a0
Fig. 2. Tectonic
scheme
of the northern
I = continuous
single-channel
detailed
carried
survey
Oceanology
of profiles
Soviet
and American
2 = DSDP fault
expeditions
4 = intensely
is shown
folds;
6 = monotonous
deformations
7 = block-ridges:
CR -Comorin
Ridge,
A.N.-Afanazy
earthquake (after the
epicenters;
Geller 31 cruise
Nikitin
of the
Ridge,
9 = abnormally R/V
transform
0E
8 = intraplate
high heat
“Dmitry
and base-
EFER -85
group.
indexes
crustal
asymmetric
of sediments
seamount
et al., 1983), numerical
and
lines.
deforma-
individual
upthrusts
ment.
of
out by other
by dashed
in km. The intraplate
spaced
and
Institute
and BB’ show the
folded and fractured
5 = closely
Basin.
profiling
from Fig. 4); the same carried
sites, 3 = Isobaths
blocks;
Indian
out by the P.P. Shirshov
are shown by solid lines (AA’
location
tion area:
Central
seismic reflection
flow points
are values
Mendeleev”;
from
10 = old
faults.
the asymmetrical folds here are mainly southward-verging with the rises’ northern slopes more intensely folded and fractured. The anticli-
9':~ , - 9 8
A
0°
0.5 °
I
1°
I
1 ,S °
I
2.5 °
I
3°
35 °
I
...'C~'%.... -
7 . . . .
.
8~
,
:?:-?,
/
~
-~
c+$s,
~1~-. ~
' . ~
2"
:
.]'~
'~-
"
':,
>~"i ',<
V E = 20.1
# o
0.5°S
0
0.5 ° I
1 ,S °
2°N
150 °
1
I
7
?V' A : I: :! ': ~,- kk ,:
:
. "
,< -, >, ~;
,7;
7:;?
:?,;7; ]" =.
sec
:i[-X-~
~, .'" .~-
6
9
~,. b ~ Z ~ ~
i.
I
'- 7 : "
Y
. . . . .
(:1
B
~
<':,[
j'
9sec
,~,~.~-~:c.~,:~
",:3
"
.
~i'
b
Fig. 4 Regional si~gle-cbarmel seisr~fic reflection profiIes carried ou~ o~ R / V " D m i t r ' v Me~deleev '' cruise 31 w i t h i a d e f o r m a t i o n area. a. Profile AA'_ b, Profile B B ' m Figs. 1 and 2.
the i n t r a p t a t e
+
V.E.=
20.1
B
99
nal arches of these basement by local depressions formed Figure
4a shows a deep graben-like
where the sediments’ compared floor.
rises are complicated by step faults.
thickness
One can see that
block
side of the depression is similarly fault-fold basement rises undoubtedly
stress;
mainly
under
(2) shearing
by tension
conditions strain
and compression
of
is always strains.
2.5 km as
parts of the sea
the fault
form
accompanied
depression
reaches
with 1.5 km in adjacent
wrench-faults compressional
on each
Results of the detailed survey
tilted. These formed as a
R/V
“Dmitry
Mendeleev”
cruise
31 continu-
result of compressional stress. It appears, however, that these two tilted fault blocks are characterized
ous seismic reflection profiling in the survey area 2 X 2.5 o near 4”s and 80”E (Figs. 1 and 2)
by counter-vergence
which
the depression
of tectonic
itself should
deformations,
be regarded
and
was covered
in great
with the most important
as a ten-
sion pattern. The available seismological data offer evidence of the existence of near-meridional compressional stress in the northern Central Indian Basin (Fitch et al., 1973; Stein and Okal, 1978); it is reasonable to explain the observed tectonic fabric as being due to shearing strain. That supposition agrees with the results of tectonophysical analysis of the mechanism for wrench-faults generation (Sherman, 1981): (1) in the lithosphere,
detail,
provided
us
data on the structure
of
the sediments and the relief of the consolidated crust within the previously identified large upwarped fault block (Fig. 3). This feature is a broad basement rise more than 1 km high. The sediment cover overlying the basement feature is l-l.2 km thick and is completely deformed and uplifted above the flat basin’s bottom, forming a swell 500 m high. The crustal block is bounded by nearmeridional fracture zones and NE-striking faults.
old transform fault N
180" d
E
90" c
25 km Fig. 5. Single-channel
seismic reflection fracture
profile
from R/V
zone. The location
“Academician
VF=lhl Kurchatov”
cruise
32 illustrating
is shown in Figs. 6 and 7 by the heavy line b.
an old near-meridional
102
The seismic reflection
configuration
fill suggests that the near-meridional are very old. The pattern tween
reflectors
within
of the onlap fracture
zones
of the relationship
the sedimentary
be-
sequence
elements.
is bounded zones
ional
orientation
ments
On
en-echelon
other
hand,
of these
the NE-striking
lent correlation
between
faults.
faults
display
displacement
the
excel-
in the base-
ment and the whole sedimentary sequence (Figs. 3 and 4). These faults are marked by a series of near-latitudinal high-angle fault scarps of the basement’s surface up’to 500 m high on the northern and southern flanks of the rise. The asymmetric folds within the sedimentary cover correspond to these high-angle faults which are considered to be reverse faults (Eittreim
and Ewing, 1972; Weis-
that
old fracture
(63-74”).
origin
block
in size and
faults:
for the
pre-sedimentary
fault
100 X 140 km
clearly
evidence
upwarped
faults.
was
in detail has the form of a parallelogram
parallel
and the buried basement scarps 500-700 m high along which the basement’s surface is displaced, seen in Fig. 5, provides
The
surveyed
and
young
The thrusts system
along
The morphological
tectonized
fault blocks
seismic reflection
NE-striking
and folds within
are of near-latitudinal
strike
and
faults the sediform an
the major
NE-striking
similarity
between
as revealed
profiles
by near
of near-merid-
the
by the regional
allows us to extrapolate
the survey results from the area covered in great detail to the whole of the intraplate deformation area. Although we do not have enough seismic reflection profiles to draw up an exact tectonic scheme of the region, it is reasonable to suppose that its interior is controlled by the afore-mentioned
faults, and that the whole intraplate
defor-
se1 et al., 1980; Geller et al., 1983). The folds are southward-verging on the northern flank and
mation area contains similar tectonized blocks. These fault blocks are sporadically distributed,
northward-verging on the southern one. They are lo-20 km long and 5-10 km wide. The intensity of the deformations decreases away from the NEstriking faults towards both the rise crest and the basin: the folds there are smaller-5-10 km long and 225 km wide-and the amplitude of the
separated by less deformed parts of the sea floor, suggesting a fault-fold mosaic framework for this part of the Indian Ocean (Fig. 2).
thrusts falls to 100 m. The form and height (100-300 m) of each fold is constant throughout the whole cross section of the deformed part of the sedimentary
cover.
Piston cores obtained on R/V “Dmitry Mendeleev” cruise 31 indicate that the uppermost deformed
sediments
of the swell consist
of slightly
lithified terrigenous pelagic clays interbedded with turbidites. The age of these is Late Miocene (5-5.5 m.y.B.P.) as dated by Radiolaria (E.M. Emelyanov and S.B. Kruglikova, pers. commun., 1984). This age is the same as that given by Weissel et al. (1980) and indicates the time post-sedimentary deformation.
of the intraplate Consedimentary
folding in the upper part of the sediments at the foot of the rise suggests that the process of folding may have continued for some time. The basement surface relief (Fig. 6) and sediment thickness (Fig. 7) of an upwarped fault block were mapped. The maps cover a section 3 X 3.5” in size in the vicinity of the area surveyed in detail. Examination of these maps indicates the strike of the main tectonic
Seismic refraction studies and observation earthquakes by Ocean Bottom Seismograph The crustal structure using an Ocean Bottom
of
of the region was studied Seismograph (OBS) at two
sites during R/V “Dmitry Mendeleev” cruise 31. Seismological observations were carried out simultaneously with the same OBS array. According the structure Indian Basin
to previous seismic refraction data, of the Earth’s crust in the Central is a typical three-layered one (Fig.
8a) (Neprochnov et al., 1981). Sediments in its northern part are up to 2.7 km thick. The average thickness of the second layer, with a seismic velocity of 4.4-5.1 the oceanic
km/s,
is 1.5 km. The third layer of
crust, with a seismic velocity of 6.2-6.8
km/s, is 3.5-6.7 km thick. Average thickness of the crust in the basin is approximately 6 km. New seismic refraction data have revealed anomalous features in the crustal structure of the Central Indian Basin (Neprochnov et al., 1986). According to these new data, the weakly deformed sections of the basin with a smooth sea floor are characterized by a typical oceanic crustal structure
103 c
b
The northern belongs
to
seismicity
part of the Central
an
(Sykes,
of M 2 4.5 and
there
observations
seismic
(Neprochnov formed and
of the Earth’s
refraction et al., 1981).
b. Model
area (80 o E and 3.5’S).
fractured
sediments;
anticlinal
basement
2 = the second
unit;
upper mantle;
crust
and upper a.
mantle
Average
model
for monotonously
c. Model
for intensely
defolded
rise (80 o E and 4” S). I = 3 = the third unit;
5 = unconsolidated
were
during
10 days of continuous
ing (Neprochnov
measurements.
4 = normal
activity
to other ocean basins.
earthquakes
The
1907
in this region More than 100
registered
at two
seismological
collision
of the
has been
proposed
continents
of Asia
in the literature
formations
has not
been
sufficiently
to develop
this reasoning
(sediments), 5.6 km/s and 6.6 km/s, and thicknesses of 1.6 km, 1.6 km and 4.6 km, respectively.
possible
mechanism
for the origination
traplate
deformations.
tinuity
is 8.2 km/s.
discon-
The whole crust in these parts
by the continental
We suggested
studied;
it
they may have recompressive stress
tempted
of the MohoroviEiC
and
as the
cause of the intraplate deformations of sediments and basement in the northern Central Indian Basin (Eittreim and Ewing, 1972; Weissel et al., 1980). However, the mechanism that generates these de-
caused
velocity
record-
tectonic evolution
(Fig. 8b). It is made up of three layers which are characterized by seismic velocities of 1.8-2.0 km/s
The seismic
sites
et al., 1986).
has only been suggested that sulted from the N-S horizontal
upper mantle.
1983.
with the OBS indicate
high seismic
small
India from
et al., 1973; Stein
between
registered
Discussion:
Fig. 8. Deep structure
Fitch
Basin
intraplate
were
as compared
I
1970;
Indian
anomalous
40 earthquakes
Seismological
82
of
and Okal, 1978). About
extraordinarily
E3 I
area
collision.
on the grounds
We have atand propose
a
of the in-
of the results
of
the first stage of our investigations (1976-1981) that the recent deformations in the oceanic crust
of the basin is about 8 km thick. The structure of the crust and upper mantle within the folded and fractured basement rise (Fig. 3) exhibits anoma-
in the northern Central Indian Basin might have been caused by a set of left-lateral strike-slip
lous features:
faults
the layers with seismic
velocities
of
of
NE-SW
orientation
2.0, 6.1, 6.9 and 7.6 km/s are 1.1, 1.3, 4.2 and 6.6 km thick, respectively (Fig. 8c), where 6.6 km is
north
the thickness
al., 1985). The strike
(unconsolidated
of the crust up to the discontinuity upper
mantle
(?)).
The generalized seismic profile between sites 215 and 218 near 2-2.5”N displays two seismic columns with similar results (Curray et al., 1982). The surface of the layer characterized by seismic velocities of 7.7 and 7.6 km/s was found at a depth of 7-9 km below the sea-floor surface. Above it, layers with velocities of 7.0 and 6.9 km/s are 2.5 and 4 km thick, respectively. The anomalous seismic refraction data suggest that intraplate deformations are not confined to the crust but extend to greater depths.
themselves
as a large
of the Indo-Australian
deformation
area
that
wrench-fault
manifested zone
in the
plate (Levchenko
of the identified
approximately
et
intraplate
coincided
with
the orientation of transform faults in the Central Indian Ridge (off the west side of the area) and with the orientation of wrench-faults which broke the northern Ninetyeast Ridge into a series of en-echelon blocks (off the east side of the area) (Fig. 9). Thus, it would be reasonable to suggest the presence of large continuous faults that perhaps cross the whole of the Central Indian Basin. None of the observed morphological features of the deformations contradicts the main concepts of wrench-fault tectonics (Moody and Hill, 1956);
104 110
90
70
Central cm/yr
Indian
also
increases
from
3-4
to 6-7.5 cm/yr in the south 1979). We consider that the relative
(Sorokhtin, displacement
20
Ridge
in the north
of the above mentioned
parts of the
plate, probably in the Late Miocene, may have been caused by the difference in the rates and
0
directions
of
boundary
(Himalaya)
northeastern less, we noted istence
plate
boundary
collision and (Sunda
the necessity
of strike-slip
faults
at
its
northern
subduction
at
Trench).
Neverthe-
to check
its
for the ex-
in the Central
Indian
Basin. 20
The results of seismic reflection profiling carried out on R/V “ Dmitry Mendeleev” cruise 31 (1984) have added two further bits of information to our former picture of the interior of the intraplate deformation area in the Central Indian Basin:
40
Fig. 9. Schematic wrench-faulting
diagram
illustrating
in the Central
rates of plate subduction
the tectonic
Indian
Basin.
model of the
Directions
are from Sorokhtin
and
(1979).
maximum-stress direction, strike of the supposed shear planes and second-order strain directions agree with the geometry of a wrench-fault tectonic system. It should be mentioned here that largescale wrench-faults are proposed as a dominant type of failure in the Earth’s crust by us and many other authors (e.g., Sherman, 1981). According to seismological data, the horizontal compressional stress within the Indo-Australian plate
off the Sunda
Island
Arc is much
weaker
(1) Individual crustal fault blocks observed in this area, which appear in the cross section as anticlinal basement rises characterized by an intensely broken surface, are of isometric quadrangular form. (2). In the intraplate deformation area these extremely deformed fault blocks alternate with less deformed parts of the sea floor; this alternation gives the area a distinctive mosaic framework. Both of these conclusions agree with the results of the tectonophysical analysis of the origin of wrench-fault zones based on a viscoelastic model carried out by Bornyakov (1981). The following are some of the typical features of wrench-fault zones revealed as a result of tectonophysical elling: (1). The development of shear
modstrain,
than the stress that is transmitted from the northern convergent plate boundary into the adjacent
accompanied by causes disruption
oceanic regions (Fitch et al., 1973). In the northernmost part of the plate, the compressional stress increased as a result of the continental collision, while its southern part subducted normally beneath the Sunda Trench. The wrenchfaulting in the Central Indian Basin may have been caused by the different resistance of the Himalayan and the Sunda Trench plate boundaries
redundant volume of sediments manifests itself in swelling and the formation of a rise characterized by a complicated morphology of the surface and by an isometric form. (2). A complicated and inhomogeneous differentiated strain field exists in wrench-fault zones. It is this inhomogeneity that
in the presence of continued spreading in the Central Indian Ridge (Fig. 9). The near meridional subduction rate of the Indo-Australian plate in the Himalaya is 4-5 cm/yr, while its NE subduction rate beneath the Sunda Trench is 6.5-7.5 cm/yr; the NE spreading rate in the
Thus, the results of geophysical observations in the field and tectonophysical modelling seem to agree. Here, we would like to refer you once more to the seismic reflection profile in Fig. 4a, showing compression and tension structural features side by side in the intraplate deformation area. We
dilatation and of sediments.
metamorphism, The resultant
brought about the existence of blocks of a different tectonic native in the zone under study.
105
believe
that the observed
tectonic
as the system of near-latitudinal and
asymmetric
have formed
folds
pattern,
in sediments,
the intraplate
to suggest
thrusts
might
only
in the Central
Basin
has been
not simply
sional
stress as such but by the relaxation
of
Indian
by compresof this
However,
we have to admit
are not enough
to prove
phase of wrench-faulting Australian
plate
true because
took
of
This
is particularly trending strike-slip
fracfaults
in the northdata can not
It is still possible framework controlled
suggest that real “fault
numerous as echelon
discrete
segments,
arrays”
(Segall and
to suggest
that
the tectonic
of the northern Central Indian Basin is by tectonic elements of two genetic
types. The old structural pattern seems been affected by the largest near-meridional form faults formed the Late
Cretaceous.
during
crustal
Failures
to have trans-
construction
in and
Therefore,
it is likely
collision
India
then
and Asia
and
that
besides
and
nonbeen
stressed
fault
stress increased
of the continents
relaxed
tectonic
unevenly,
framework.
of thus
This ob-
the environmendeformations.
It seems to be more correct to speak about a zone of shearing strains characterized by a complicated structure
which
NE-SW
trending
system
formed
of ancient
rather
due to the interaction
wrench-fault failures
than just about
We
would
like
tectonics
in the oceanic
a wrench-fault
to note,
of
with
a
crust
zone.
however,
that
it is
premature as yet to make any positive claims about the mechanism which generated these deformations within the Indo-Australian plate.
Acknowledgements
The authors
wish to express
their appreciation
to the scientific staff and crew of the R/V “Dmitry Mendeleev”, who contributed to the successful implementation of the seismic investigations during cruise 31.
References
in
structural
features of the oceanic crust, which developed result of sea-floor spreading, tend to display strikes.
the compressional
due to the continued
allows us to reconsider
ments of such faults there. On the other hand, the data are too sparse to deny their existence. Furthermore, the results of some field studies and consist
Hence,
variously
tal regime of the origin of intraplate
be considered to prove conclusively the existence of extended NE-trending faults in the Central Indian Basin as we have found only short seg-
traces
comprised
recent
had
of the plate
servation
has been registered nowhere except ern Ninetyeast Ridge. The available
commonly arranged Pollard, 1980).
part
that the proposed
ture zones by recent NE-trending
modelling
was inhomogeneous
that the presented
the offset of old N-S
tectonophysical
and
had undergone
the whole
in this part of the Indoplace.
and as that
fractured blocks.
and folded in the study area,
lithosphere
affecting
stress due to wrench-faulting. data
deformations monolithic,
Therefore,
that the origination
deformations affected
ments were fractured but the plate’s
en-echelon
in a zone of shear strains.
it is reasonable
as well
as a two the
observed near-meridional transform faults there may exist smaller near-latitudinal cracks and initial zones of weakness in the crust parallel to the palaeorift valley. A prolonged stable period of sedimentation was followed by the Late Miocene tectonic activity. Recent tectonic intraplate deformations in sediments and basement and NE-striking faults that determine the recent structural pattern seem to have been affected by this event. In the Late Miocene, primarily undeformed flat-lying sedi-
Bomyakov,
S.A., 1981. Tectonophysical
of transform
zone’s origination
In: N.A. Logachev
analyses
and S.I. Sherman
lems of Fault Tectonics.
of a process
using the viscoelastic
Nauka,
(Editors),
Novosibirsk,
model.
The Prob-
pp. 26-44
(in
Russian). Chekunov, G.E.,
A.V., Sollogub, Rusakov,
AS.,
V.B., Starostenko,
O.M.,
Kozlenko,
1984. The structure
Geotectonica, Structure,
tectonics,
em Indian
Ocean.
tors), The Ocean Ocean. Eittreim, Indian
Indian
1: 24-33
J.R., Emmel,
Plenum
Kostjukevich,
minimum
in
of geopotential.
(in Russian).
F.J., Moore,
D.G. and Raitt, R.W., 1982.
and geological In: A.E.M. Basins
history
Naim
and Margins,
of the northeast-
and F.G. Stehli (EdiVol. 6. The Indian
Press, New York, N.Y., pp. 399-450.
S.L. and Ewing, Ocean.
and
of the earth’ crust and mantle
the zone of the global Curray,
V.I., Kharechko,
V.G.
J., 1972. Mid-plate
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M.H.
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Everringam,
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LB., 1973.
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Earth
Planet.
Sci. Lett.,
CA.,
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deformation
R.N.,
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in the central
Indian
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L.R. and Neprochnov, in the central
Indian
YuP.,
1985.
Basin.
Geo-
tectonics.
Bull.
Yu.P., Merklin,
The thickness
reflection
Geophysics
data.
of sedimentary
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of the Ocean,
anic Floor. Nauka, Neprochnov,
L.R. and Milanovsky,
and structure
Yu.P.,
Yu.P.
Neprochnov
pp. 206-242
Elnikov,
I.N.,
L.N., Sedov, V.V. and Shishkina,
structure
of the earth’s
zrukov
Geophysics Moscow, Neprochnov, L.G.,
of the Eastern pp. 140-165 Yu.P.,
Grinko,
(Editors), Indian
1986. New data
A.F.,
N.A., 1981. The In: P.L. Be-
The Geology
Ocean
Floor.
and
Nauka,
(in Russian).
Sedov,
V.V., Pokrishkin,
B.N., Ostrovsky, on the earth’s
Fisher, Ocean,
Sherman,
A.A., Akentjev,
crust and seismicity
B.V., of the
Indian
5-26
Oceans.
Dokl.
Akad.
(in Russian).
R.L.,
1974.
Evolution
with emphasis
of the east-
on the tectonic
D.D., 1980. Mechanics
setting
of discontinuous
Res., 85: 4337-4350.
S.I., 1981. The strike-slip
lithosphere.
and transform
In: N.A. Logachev
faults in the
and S.I. Sherman
of Fault Tectonics.
Nauka,
(Editors),
Novosibirsk,
pp.
(in Russian). O.G.,
1979. The division
In: O.G. Sorokhtin 2. Geodynamics.
(Editor), Nauka,
of lithosphere
Geophysics
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of the ocean,
pp. 151-157
Vol.
(in Rus-
sian). Stein, S. and Okal, E.A., 1978. Seismicity Ridge
of the Indian
area.
Evidence
plate. J. Geophys.
Sykes, L.R., 1970. Seismicity nascent
Island
and tectonics
for internal
Res., 83: 2233-2246.
of the Indian
arc between
of the
deformation
Ceylon
Ocean
and possible
and Australia.
J. Geo-
phys. Res., 75: 5041-5055. Weissel,
J.K., Anderson,
mation
A.A. and Kholopov,
and
Ridge. Geol. Sot. Am. Bull., 85: 684-702.
Segall, P. and Pollard,
Ninetyeast
(in Russian).
and seismicity.
and Yu.P. Neprochnov
(Editor), of the Oce-
Neprochnova,
Rikunov,
crust
V.E., 1979.
cover based on
Vol. 1. Geophysics
Moscow,
and
Indian
of the Ninetyeast
Sorokhtin,
Geol. Sot. Am., 67: 1207-1246.
seismic
J.G.
The Problems
(in Russian).
J.D. and Hill, M.J., 1956. Wrench-fault
Neprochnov,
Sclater,
faults. J. Geophys.
Res., 88: 1018-1032.
O.V., Merklin,
folded
tectonica, Moody,
R.L. and Anderson,
J. Geophys.
Levchenko, The
Weissel,
and intraplate
Ocean,
of the Atlantic
USSR, 290: 1448-1453
central
18: 345-356. Geller,
basins Nauk.
Zonenshain,
R.N. and Geller,
of the Indo-Australian L.P.
Geodynamics.
and Nedra,
Savostin, Moscow,
CA.,
plate. Nature, L.A.,
1979.
1980. Defor287: 284-291.
Introduction
311 pp (in Russian).
in
The structure
YURI
89
B.V.. Amsterdam
- Printed
in The Netherlands
and tectonics of the intraplate in the Indian Ocean
P. NEPROCHNOV,
OLEG
V. LEVCHENKO,
and VLADIMIR
deformation
LEV
area
R. MERKLIN
V. SEDOV
P.P. Shirshov Institute of Oceanology, Moscow 117218 (U.S.S.R.) (Received
February
2, 1987; revised version accepted
April 6, 1988)
Abstract Neprochnov,
Y.P., Levchenko,
deformation Intense
tectonic
formed
of sediments
reflection
by the P.P. Shirshov
NE-trending
area
profiles
Institute
of crustal
and basement
from
unusual
the northern
of Oceanology
of these deformations.
by a mosaic
L.R. and Sedov, V.V., 1988. The structure
and tectonics
of the intraplate
Tectonophysics, 156:89-106
Ocean.
deformations
can be seen on seismic collected
O.V., Merklin,
area in the Indian
for the interior
Central
Indian
of the USSR
The intraplate
Academy
deformation
area
blocks which have been severely deformed
of the oceanic
Basin.
lithosphere
plates
lO,OOO-mile long CSP profiles
of Sciences
allow
has a complicated
or tilted alternating
delineation
tectonic
of a
framework,
with less deformed
parts
of the sea floor. The results of a detailed two genetic indicate Ocean
types:
an anomalous Bottom
CSP grid survey reveal that these uplifted
old nearly
meridional
structure
Seismographs
fracture
of the crust
have proved
zones, and young
and upper
mantle
faulted
within
that there is high-level
blocks are bounded
NE-striking
faults.
these blocks.
intraplate
by tectonic
Seismological
seismicity
faults of
The seismic refraction
results
observations
in the northern
from
Central
Indian
Basin. The intraplate
deformation
area is supposed
to correspond
result of the stress difference
in the Indo-Australian
Asia
in the Central
along
continental
with
part continuously plate, NE-SW the sediments the system near-latitudinal deformation
spreading
collision
led to an increase
subducted trending
beneath
shearing
and basement, of ancient scarps
failures
spreading
and
normal
In the complicated
on seismic reflection
in the
zone of shearing collision
subduction
stress in the northernmost
apparently
to the mid-oceanic
area might be partly
Ridge
the Sunda Trench.
observed
parallel
Indian
in compressional
stress abated,
to a large-scale
plate due to the continued
oceanic ridge
profiles. crust
NE-SW
in the Sunda
as a
of India and
Island
zone between
Arc.
This
these parts of the
as a result of folding
trending
(near-meridional
axis). The mosaic
that formed
part of the plate, while its southern
transitional
in the Late Miocene,
strains
of the continents
fault-fold
wrench-fault transform
and faulting
tectonics
faults
framework
and,
of
affected perhaps,
of the intraplate
a result of this interaction.
Introduction
are normally recorded only at their boundaries, while the Central Indian Basin is located within
High present-day seismicity, abnormally high heat flow, intense tectonic deformations of sediments and basement, as well as other unusual geophysical characteristics (see e.g., Weissel et al., 1980) make the Central Indian Basin unique among oceanic basins. These phenomena are not typical of the interiors of lithospheric plates and
the one-piece Indo-Australian plate (see, e.g., Sclater and Fisher, 1974; Zonenshain and Savostin, 1979). These seemingly contradictory facts aronsed our interest in the area. Until recently, the tectonic aspects of the peculiarity of the Central Indian Basin were mainly based on studies of the high intraplate seismicity.
004O-1951/88/$03.50
0 1988 Elsevier
Science Publishers
B.V.
90
Sykes (1970) proposed a convergent plate boundary and a nascent island arc between Sri Lanka and the Cocos Islands. Later, a boundary consisting of left-lateral strike-slip motion between the Indian and Australian plates along the
northern Ninetyeast Ridge was suggested (Stein and Okal, 1978). At present, there are more than ten different explanations of the nature of the largest free-air gravity low and the most prominent low of the total gravimetric geoid in the
/ \ 2c I
-
i \
1cI-
c)-
/
/ 1c)-‘
< .~ 1
./ ‘
2c I-
I,/\ ,_ 70
80
Fig. 1. Continuous single-channel
J
90
1Of3
seismic reflection profiles carried out by the P.P. Shirshov Institute of Oceanology of the USSR
Academy of Sciences in the Eastern Indian Ocean. I = profiles and detailed survey areas of R/V “Dmitry (heavy lines AA’ and BB’
show the location of the profiles from Fig. 4); 2 = the same for 1976-1981 4 = isobaths in km.
Mendeleev” cruise 31
cruises;
3 = DSDP
sites;
91
Indian
Ocean south of Sri Lanka (Chekunov
1984)
none
accepted.
of
which
The mechanism
heat flow recorded spheric
seems
to
be
and source
generally
of the high
there, which is related
deformation,
to litho-
unclear
(Geller
et al., 1983). This paper deals with intense
tectonic
deformation
of sediments
are pronounced which
also remain
et al.,
and
basement,
on seismic reflection
are the most conspicuous
which
profiles
anomalous
and phe-
nomena. The mid-plate
deformation
of sediments
and
basement in the Central Indian Basin were first reported by Eittreim and Ewing (1972) who suggested that their existence was the result creasing compressional stress in the interior
of inof the
Indo-Australian plate due to the collision between the Indian subcontinent and Asia. That hypothesis still holds true. The beginning of these deformations is believed to be connected with the Miocene Himalayan erogenic phase of this collision (Weisse1 et al., 1980). The first investigations of the intraplate deformations in the Central Indian Basin were carried out by Soviet scientists of the P.P. Shirshov Institute of Oceanology in 1976 on the R/V “Vityaz” cruise 58 (Neprochnov et al., 1979) and continued in 1980 on the R/V ‘Dmitry Mendeleev” cruise 25 and in 1981 on the R/V “Academician Kurchatov” cruise 32 (Levchenko et al., 1985). In 1984 on the R/V “Dmitry Mendeleev” cruise 31, investigations connected with these intraplate deformations out, including two highly detailed physical
were carried geological-geo-
surveys in the areas shown in Fig. 1. New
important data on the structure and seismicity of the region were obtained. We hope that the seismic reflection profiling data collected during our cruises and recent research into the tectonic framework of the intraplate deformation area will throw some light on the problem Results of continuous
of its genesis.
seismic profiling of the re-
(Weissel
et al., 1980)
to delineate
the unique
there (Levchenko (azimuth
900-1000
and
deformation
62-75”)
1600
km
are located
between
1’s
4 o N and 4 o S of the western
eastern
(near
long
and
to 89“ E (Fig. and
9’S
and
(near 76 o E)
89” E) sides of the delineated
intraplate
deformation
framework
of this area is inhomogeneous
characterized
area
were traced in a NE-trending
km wide from 77”30’E
2). They between
intraplate
et al., 1985).
The deformations band
they have made it possible
area
by extremely
respectively.
deformed
The and is
crustal blocks
that are conspicuous against the weaker and more monotonous deformations of sediments and basement.
About
15 of these large tectonized
blocks,
which are either symmetrically upwarped (Fig. 3) or asymmetrically tilted (Fig. 4), have been identified up to now. They appear in the cross section as gently sloping anticlinal basement rises from 50 to 200-300 km wide and l-2 km high, corresponding conformably to sea-floor swells from 100 to 600 m high. On the rises, the l-2 km thick sediment cover is crumpled into asymmetric folds (mostly with high-angle sloping southern limbs) up to several hundred meters high. The sediments and basement between the tectonized fault blocks are less deformed and are unconformably by the undisturbed sediments, 100-400 which form the flat basin’s
bottom.
overlaid m thick,
In the north-
ern part of the area, some of the fault blocks totally buried km thick.
under
flat-lying
sediments
are
up to 0.8
Four regional seismic reflection profiles obtained on the R/V “Dmitry Mendeleev” cruise 31 have supplemented the grid of profiles covering the intraplate deformation area in the Central Indian Basin (Fig. 1). The appearance of the fault-fold deformations on these profiles coincides with the predicted boundaries intraplate deformation area
of the identified (Fig. 2) but the
gion
seismic reflection records reveal that there is a great variety in the fault blocks and that the area
The seismic reflection data we collected during the 1976-1981 cruises have given us a clear picture of the morphology of the deformations in sediments and basement in the Central Indian Basin. Together with the published American data
has a more complex tectonic framework than we believed earlier (Levchenko et al., 1985). Two large tilted fault blocks, 100 and 200 km long, were traversed with seismic reflection profiles near 2.5”S, 81” E and 1” N, 83”E respectively (Fig. 4). In contrast to most of the folds already studied,
92
a0
Fig. 2. Tectonic
scheme
of the northern
I = continuous
single-channel
detailed
carried
survey
Oceanology
of profiles
Soviet
and American
2 = DSDP fault
expeditions
4 = intensely
is shown
folds;
6 = monotonous
deformations
7 = block-ridges:
CR -Comorin
Ridge,
A.N.-Afanazy
earthquake (after the
epicenters;
Geller 31 cruise
Nikitin
of the
Ridge,
9 = abnormally R/V
transform
0E
8 = intraplate
high heat
“Dmitry
and base-
EFER -85
group.
indexes
crustal
asymmetric
of sediments
seamount
et al., 1983), numerical
and
lines.
deforma-
individual
upthrusts
ment.
of
out by other
by dashed
in km. The intraplate
spaced
and
Institute
and BB’ show the
folded and fractured
5 = closely
Basin.
profiling
from Fig. 4); the same carried
sites, 3 = Isobaths
blocks;
Indian
out by the P.P. Shirshov
are shown by solid lines (AA’
location
tion area:
Central
seismic reflection
flow points
are values
Mendeleev”;
from
10 = old
faults.
the asymmetrical folds here are mainly southward-verging with the rises’ northern slopes more intensely folded and fractured. The anticli-
9':~ , - 9 8
A
0°
0.5 °
I
1°
I
1 ,S °
I
2.5 °
I
3°
35 °
I
...'C~'%.... -
7 . . . .
.
8~
,
:?:-?,
/
~
-~
c+$s,
~1~-. ~
' . ~
2"
:
.]'~
'~-
"
':,
>~"i ',<
V E = 20.1
# o
0.5°S
0
0.5 ° I
1 ,S °
2°N
150 °
1
I
7
?V' A : I: :! ': ~,- kk ,:
:
. "
,< -, >, ~;
,7;
7:;?
:?,;7; ]" =.
sec
:i[-X-~
~, .'" .~-
6
9
~,. b ~ Z ~ ~
i.
I
'- 7 : "
Y
. . . . .
(:1
B
~
<':,[
j'
9sec
,~,~.~-~:c.~,:~
",:3
"
.
~i'
b
Fig. 4 Regional si~gle-cbarmel seisr~fic reflection profiIes carried ou~ o~ R / V " D m i t r ' v Me~deleev '' cruise 31 w i t h i a d e f o r m a t i o n area. a. Profile AA'_ b, Profile B B ' m Figs. 1 and 2.
the i n t r a p t a t e
+
V.E.=
20.1
B
99
nal arches of these basement by local depressions formed Figure
4a shows a deep graben-like
where the sediments’ compared floor.
rises are complicated by step faults.
thickness
One can see that
block
side of the depression is similarly fault-fold basement rises undoubtedly
stress;
mainly
under
(2) shearing
by tension
conditions strain
and compression
of
is always strains.
2.5 km as
parts of the sea
the fault
form
accompanied
depression
reaches
with 1.5 km in adjacent
wrench-faults compressional
on each
Results of the detailed survey
tilted. These formed as a
R/V
“Dmitry
Mendeleev”
cruise
31 continu-
result of compressional stress. It appears, however, that these two tilted fault blocks are characterized
ous seismic reflection profiling in the survey area 2 X 2.5 o near 4”s and 80”E (Figs. 1 and 2)
by counter-vergence
which
the depression
of tectonic
itself should
deformations,
be regarded
and
was covered
in great
with the most important
as a ten-
sion pattern. The available seismological data offer evidence of the existence of near-meridional compressional stress in the northern Central Indian Basin (Fitch et al., 1973; Stein and Okal, 1978); it is reasonable to explain the observed tectonic fabric as being due to shearing strain. That supposition agrees with the results of tectonophysical analysis of the mechanism for wrench-faults generation (Sherman, 1981): (1) in the lithosphere,
detail,
provided
us
data on the structure
of
the sediments and the relief of the consolidated crust within the previously identified large upwarped fault block (Fig. 3). This feature is a broad basement rise more than 1 km high. The sediment cover overlying the basement feature is l-l.2 km thick and is completely deformed and uplifted above the flat basin’s bottom, forming a swell 500 m high. The crustal block is bounded by nearmeridional fracture zones and NE-striking faults.
old transform fault N
180" d
E
90" c
25 km Fig. 5. Single-channel
seismic reflection fracture
profile
from R/V
zone. The location
“Academician
VF=lhl Kurchatov”
cruise
32 illustrating
is shown in Figs. 6 and 7 by the heavy line b.
an old near-meridional
102
The seismic reflection
configuration
fill suggests that the near-meridional are very old. The pattern tween
reflectors
within
of the onlap fracture
zones
of the relationship
the sedimentary
be-
sequence
elements.
is bounded zones
ional
orientation
ments
On
en-echelon
other
hand,
of these
the NE-striking
lent correlation
between
faults.
faults
display
displacement
the
excel-
in the base-
ment and the whole sedimentary sequence (Figs. 3 and 4). These faults are marked by a series of near-latitudinal high-angle fault scarps of the basement’s surface up’to 500 m high on the northern and southern flanks of the rise. The asymmetric folds within the sedimentary cover correspond to these high-angle faults which are considered to be reverse faults (Eittreim
and Ewing, 1972; Weis-
that
old fracture
(63-74”).
origin
block
in size and
faults:
for the
pre-sedimentary
fault
100 X 140 km
clearly
evidence
upwarped
faults.
was
in detail has the form of a parallelogram
parallel
and the buried basement scarps 500-700 m high along which the basement’s surface is displaced, seen in Fig. 5, provides
The
surveyed
and
young
The thrusts system
along
The morphological
tectonized
fault blocks
seismic reflection
NE-striking
and folds within
are of near-latitudinal
strike
and
faults the sediform an
the major
NE-striking
similarity
between
as revealed
profiles
by near
of near-merid-
the
by the regional
allows us to extrapolate
the survey results from the area covered in great detail to the whole of the intraplate deformation area. Although we do not have enough seismic reflection profiles to draw up an exact tectonic scheme of the region, it is reasonable to suppose that its interior is controlled by the afore-mentioned
faults, and that the whole intraplate
defor-
se1 et al., 1980; Geller et al., 1983). The folds are southward-verging on the northern flank and
mation area contains similar tectonized blocks. These fault blocks are sporadically distributed,
northward-verging on the southern one. They are lo-20 km long and 5-10 km wide. The intensity of the deformations decreases away from the NEstriking faults towards both the rise crest and the basin: the folds there are smaller-5-10 km long and 225 km wide-and the amplitude of the
separated by less deformed parts of the sea floor, suggesting a fault-fold mosaic framework for this part of the Indian Ocean (Fig. 2).
thrusts falls to 100 m. The form and height (100-300 m) of each fold is constant throughout the whole cross section of the deformed part of the sedimentary
cover.
Piston cores obtained on R/V “Dmitry Mendeleev” cruise 31 indicate that the uppermost deformed
sediments
of the swell consist
of slightly
lithified terrigenous pelagic clays interbedded with turbidites. The age of these is Late Miocene (5-5.5 m.y.B.P.) as dated by Radiolaria (E.M. Emelyanov and S.B. Kruglikova, pers. commun., 1984). This age is the same as that given by Weissel et al. (1980) and indicates the time post-sedimentary deformation.
of the intraplate Consedimentary
folding in the upper part of the sediments at the foot of the rise suggests that the process of folding may have continued for some time. The basement surface relief (Fig. 6) and sediment thickness (Fig. 7) of an upwarped fault block were mapped. The maps cover a section 3 X 3.5” in size in the vicinity of the area surveyed in detail. Examination of these maps indicates the strike of the main tectonic
Seismic refraction studies and observation earthquakes by Ocean Bottom Seismograph The crustal structure using an Ocean Bottom
of
of the region was studied Seismograph (OBS) at two
sites during R/V “Dmitry Mendeleev” cruise 31. Seismological observations were carried out simultaneously with the same OBS array. According the structure Indian Basin
to previous seismic refraction data, of the Earth’s crust in the Central is a typical three-layered one (Fig.
8a) (Neprochnov et al., 1981). Sediments in its northern part are up to 2.7 km thick. The average thickness of the second layer, with a seismic velocity of 4.4-5.1 the oceanic
km/s,
is 1.5 km. The third layer of
crust, with a seismic velocity of 6.2-6.8
km/s, is 3.5-6.7 km thick. Average thickness of the crust in the basin is approximately 6 km. New seismic refraction data have revealed anomalous features in the crustal structure of the Central Indian Basin (Neprochnov et al., 1986). According to these new data, the weakly deformed sections of the basin with a smooth sea floor are characterized by a typical oceanic crustal structure
103 c
b
The northern belongs
to
seismicity
part of the Central
an
(Sykes,
of M 2 4.5 and
there
observations
seismic
(Neprochnov formed and
of the Earth’s
refraction et al., 1981).
b. Model
area (80 o E and 3.5’S).
fractured
sediments;
anticlinal
basement
2 = the second
unit;
upper mantle;
crust
and upper a.
mantle
Average
model
for monotonously
c. Model
for intensely
defolded
rise (80 o E and 4” S). I = 3 = the third unit;
5 = unconsolidated
were
during
10 days of continuous
ing (Neprochnov
measurements.
4 = normal
activity
to other ocean basins.
earthquakes
The
1907
in this region More than 100
registered
at two
seismological
collision
of the
has been
proposed
continents
of Asia
in the literature
formations
has not
been
sufficiently
to develop
this reasoning
(sediments), 5.6 km/s and 6.6 km/s, and thicknesses of 1.6 km, 1.6 km and 4.6 km, respectively.
possible
mechanism
for the origination
traplate
deformations.
tinuity
is 8.2 km/s.
discon-
The whole crust in these parts
by the continental
We suggested
studied;
it
they may have recompressive stress
tempted
of the MohoroviEiC
and
as the
cause of the intraplate deformations of sediments and basement in the northern Central Indian Basin (Eittreim and Ewing, 1972; Weissel et al., 1980). However, the mechanism that generates these de-
caused
velocity
record-
tectonic evolution
(Fig. 8b). It is made up of three layers which are characterized by seismic velocities of 1.8-2.0 km/s
The seismic
sites
et al., 1986).
has only been suggested that sulted from the N-S horizontal
upper mantle.
1983.
with the OBS indicate
high seismic
small
India from
et al., 1973; Stein
between
registered
Discussion:
Fig. 8. Deep structure
Fitch
Basin
intraplate
were
as compared
I
1970;
Indian
anomalous
40 earthquakes
Seismological
82
of
and Okal, 1978). About
extraordinarily
E3 I
area
collision.
on the grounds
We have atand propose
a
of the in-
of the results
of
the first stage of our investigations (1976-1981) that the recent deformations in the oceanic crust
of the basin is about 8 km thick. The structure of the crust and upper mantle within the folded and fractured basement rise (Fig. 3) exhibits anoma-
in the northern Central Indian Basin might have been caused by a set of left-lateral strike-slip
lous features:
faults
the layers with seismic
velocities
of
of
NE-SW
orientation
2.0, 6.1, 6.9 and 7.6 km/s are 1.1, 1.3, 4.2 and 6.6 km thick, respectively (Fig. 8c), where 6.6 km is
north
the thickness
al., 1985). The strike
(unconsolidated
of the crust up to the discontinuity upper
mantle
(?)).
The generalized seismic profile between sites 215 and 218 near 2-2.5”N displays two seismic columns with similar results (Curray et al., 1982). The surface of the layer characterized by seismic velocities of 7.7 and 7.6 km/s was found at a depth of 7-9 km below the sea-floor surface. Above it, layers with velocities of 7.0 and 6.9 km/s are 2.5 and 4 km thick, respectively. The anomalous seismic refraction data suggest that intraplate deformations are not confined to the crust but extend to greater depths.
themselves
as a large
of the Indo-Australian
deformation
area
that
wrench-fault
manifested zone
in the
plate (Levchenko
of the identified
approximately
et
intraplate
coincided
with
the orientation of transform faults in the Central Indian Ridge (off the west side of the area) and with the orientation of wrench-faults which broke the northern Ninetyeast Ridge into a series of en-echelon blocks (off the east side of the area) (Fig. 9). Thus, it would be reasonable to suggest the presence of large continuous faults that perhaps cross the whole of the Central Indian Basin. None of the observed morphological features of the deformations contradicts the main concepts of wrench-fault tectonics (Moody and Hill, 1956);
104 110
90
70
Central cm/yr
Indian
also
increases
from
3-4
to 6-7.5 cm/yr in the south 1979). We consider that the relative
(Sorokhtin, displacement
20
Ridge
in the north
of the above mentioned
parts of the
plate, probably in the Late Miocene, may have been caused by the difference in the rates and
0
directions
of
boundary
(Himalaya)
northeastern less, we noted istence
plate
boundary
collision and (Sunda
the necessity
of strike-slip
faults
at
its
northern
subduction
at
Trench).
Neverthe-
to check
its
for the ex-
in the Central
Indian
Basin. 20
The results of seismic reflection profiling carried out on R/V “ Dmitry Mendeleev” cruise 31 (1984) have added two further bits of information to our former picture of the interior of the intraplate deformation area in the Central Indian Basin:
40
Fig. 9. Schematic wrench-faulting
diagram
illustrating
in the Central
rates of plate subduction
the tectonic
Indian
Basin.
model of the
Directions
are from Sorokhtin
and
(1979).
maximum-stress direction, strike of the supposed shear planes and second-order strain directions agree with the geometry of a wrench-fault tectonic system. It should be mentioned here that largescale wrench-faults are proposed as a dominant type of failure in the Earth’s crust by us and many other authors (e.g., Sherman, 1981). According to seismological data, the horizontal compressional stress within the Indo-Australian plate
off the Sunda
Island
Arc is much
weaker
(1) Individual crustal fault blocks observed in this area, which appear in the cross section as anticlinal basement rises characterized by an intensely broken surface, are of isometric quadrangular form. (2). In the intraplate deformation area these extremely deformed fault blocks alternate with less deformed parts of the sea floor; this alternation gives the area a distinctive mosaic framework. Both of these conclusions agree with the results of the tectonophysical analysis of the origin of wrench-fault zones based on a viscoelastic model carried out by Bornyakov (1981). The following are some of the typical features of wrench-fault zones revealed as a result of tectonophysical elling: (1). The development of shear
modstrain,
than the stress that is transmitted from the northern convergent plate boundary into the adjacent
accompanied by causes disruption
oceanic regions (Fitch et al., 1973). In the northernmost part of the plate, the compressional stress increased as a result of the continental collision, while its southern part subducted normally beneath the Sunda Trench. The wrenchfaulting in the Central Indian Basin may have been caused by the different resistance of the Himalayan and the Sunda Trench plate boundaries
redundant volume of sediments manifests itself in swelling and the formation of a rise characterized by a complicated morphology of the surface and by an isometric form. (2). A complicated and inhomogeneous differentiated strain field exists in wrench-fault zones. It is this inhomogeneity that
in the presence of continued spreading in the Central Indian Ridge (Fig. 9). The near meridional subduction rate of the Indo-Australian plate in the Himalaya is 4-5 cm/yr, while its NE subduction rate beneath the Sunda Trench is 6.5-7.5 cm/yr; the NE spreading rate in the
Thus, the results of geophysical observations in the field and tectonophysical modelling seem to agree. Here, we would like to refer you once more to the seismic reflection profile in Fig. 4a, showing compression and tension structural features side by side in the intraplate deformation area. We
dilatation and of sediments.
metamorphism, The resultant
brought about the existence of blocks of a different tectonic native in the zone under study.
105
believe
that the observed
tectonic
as the system of near-latitudinal and
asymmetric
have formed
folds
pattern,
in sediments,
the intraplate
to suggest
thrusts
might
only
in the Central
Basin
has been
not simply
sional
stress as such but by the relaxation
of
Indian
by compresof this
However,
we have to admit
are not enough
to prove
phase of wrench-faulting Australian
plate
true because
took
of
This
is particularly trending strike-slip
fracfaults
in the northdata can not
It is still possible framework controlled
suggest that real “fault
numerous as echelon
discrete
segments,
arrays”
(Segall and
to suggest
that
the tectonic
of the northern Central Indian Basin is by tectonic elements of two genetic
types. The old structural pattern seems been affected by the largest near-meridional form faults formed the Late
Cretaceous.
during
crustal
Failures
to have trans-
construction
in and
Therefore,
it is likely
collision
India
then
and Asia
and
that
besides
and
nonbeen
stressed
fault
stress increased
of the continents
relaxed
tectonic
unevenly,
framework.
of thus
This ob-
the environmendeformations.
It seems to be more correct to speak about a zone of shearing strains characterized by a complicated structure
which
NE-SW
trending
system
formed
of ancient
rather
due to the interaction
wrench-fault failures
than just about
We
would
like
tectonics
in the oceanic
a wrench-fault
to note,
of
with
a
crust
zone.
however,
that
it is
premature as yet to make any positive claims about the mechanism which generated these deformations within the Indo-Australian plate.
Acknowledgements
The authors
wish to express
their appreciation
to the scientific staff and crew of the R/V “Dmitry Mendeleev”, who contributed to the successful implementation of the seismic investigations during cruise 31.
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