articolo malik.pdf


Key  words active faults – Northwestern Himalayan
Front – paleoearthquake – thrust and right lateral
strike-slip faults – slip-partitioning

1.  Introduction

Active faults are considered to be the source
for earthquakes in the seismically-active zones of
the world. Their identification bears significant

importance towards recognizing the seismic haz-
ard of these zones. Identification of active faults is
of prime importance in the Himalayan region, one
of the most seismically active intercontinental
regions of the world. Ongoing crustal deforma-
tion is well reflected by the occurrence of small-,
medium- and large-magnitude earthquakes along
the Himalayan arc. The most prominent large-
magnitude events that struck the foothill zone of
Himalaya in the span of the last 100-120 years are
the 1897 Shillong (M 8.7), 1905 Kangra (M 8.6),
1934 Bihar (M 8.4) and 1950 Upper Assam (M
8.5) earthquakes (Seeber and Armbruster, 1981;
Yeats et al., 1997) (fig. 1a). Along with these

917

ANNALS  OF  GEOPHYSICS, VOL.  46, N.  5, October  2003

Mailing address: Dr. Javed N. Malik, Department of
Civil Engineering, Indian Institute of Technology, Kanpur
208 016, India; e-mail: javed@iitk.ac.in

Active faults and related Late Quaternary
deformation along the Northwestern

Himalayan Frontal Zone, India

Javed N. Malik (1) and Takashi Nakata (2)
(1) Department of Civil Engineering, Indian Institute of Technology, Kanpur, India

(2) Department of Geography, Hiroshima University, Higashi Hiroshima, Japan 

Abstract
Numerous newly-identified traces of active faults in the Himalayan foothill zone along the HFF around Chandigarh, in
Pinjore Dun, along the piedmont zone of the Lower Siwalik hill front and within the Lower Tertiary hill range reveal the
pattern of thrust and strike-slip faulting, striking parallel to the principal structural trend (NNW-SSE) of the orogenic
belt. The active Chandigarh Fault, Pinjore Garden Fault and Barsar thrust have vertically dislocated, warped and back-
tilted fluvial and alluvial-fan surfaces made up of Late Pleistocene-Holocene sediments. West- and southwest-facing
fault scarplets with heights ranging from 12 to 50 m along these faults suggest continued tectonic movement through
Late Pleistocene to recent times. Gentle warping and backtilting of the terraces on the hanging wall sides of the faults
indicate fault-bend folding. These active faults are the manifestation of north-dipping imbricated thrust faults branching
out from the major fault systems like the Main Boundary Fault (MBF) and Himalayan Frontal Fault (HFF), probably
merging down northward into a décollement. The Taksal Fault, striking NNW-SSE, shows prominent right-lateral move-
ment marked by lateral offset of streams and younger Quaternary terraces and occupies a narrow deep linear valley along
the fault trace. Right stepping along this fault has resulted in formation of a small pull-apart basin. Fault scarplets facing
ENE and WSW are the manifestation of dip-slip movement. This fault is an example of slip-partitioning between the
strike-slip and thrust faults, suggesting ongoing oblique convergence of the Indian plate and northward migration of a
tectonic sliver. Slip rate along the Taksal Fault has been calculated as 2.8 mm/yr. Preliminary trench investigation at the
base of the Chandigarh Fault Scarp has revealed total displacement of 3.5 m along a low angle thrust fault with variable
dip of 20° to 46° due northeast, possibly the result of one large magnitude (Mw 7) prehistoric earthquake. Taking into
consideration the height of the Pinjore surface (20 to 25 m), tentative age (8.9 ± 1.9 ka), displacement during one event
and average angle of fault dip (25°) gives slip rate of about 6.3 ± 2 mm/yr, a rate of horizontal shortening of 5.8 ± 1.8
mm/yr and recurrence of faulting of 555 ± 118 years along the Himalayan Frontal Fault.



events, few moderate earthquakes with M > 6 < 7
have also been recorded in recent years, viz., 1988
Bihar-Nepal (M 6.6); 1991 Uttarkashi (M 6.6) and
1999 Chamoli (M 6.5) events. It is believed that

although there are few large and moderate quakes
along the arc, energy is accumulating in the areas
confined between large magnitude events, desig-
nated as seismic gaps. The area between the 1905

918

Javed N. Malik and Takashi Nakata

X
X

X

X

75° 80° 85° 90° 95° 30°

25°

35°

30°

Srinagar

Lahore

Delhi

Kathmandu

Shillong

T I B E T A N
P L A T E A UZ o n e o f

I n t e r m e d i a t e S e i s m
i c i t y

Dehra Dun

I N D O  - G A N G E T I C P L A I N S

H I M A L AYA N
F RO N T

1885

A.D. 25

1905

1934 1897

1950
1947

1833

1803

V

V

V

V
V

V
V

V

V

Chandigarh

Study area

Fig.  1a,b.  a) Map showing meizoseismal zones of four great earthquakes along Himalayan Front and other large
magnitude events (after Yeats and Thakur, 1998). Box marks the study area around Chandigarh. b) Generalized
tectonic framework of Himalaya and its surrounding area. ITSZ - Indus Tsangpo Suture Zone; MCT - Main
Central Thrust; MBF - Main Boundary Fault; HFF - Himalayan Frontal Fault; SRFF - Salt Range Front Fault;
KSFF - Kirthar Sulaiman Front Fault; Sub-H - Sub Himalaya.

5000 1000 km

a

b



Kangra and 1934 Bihar-Nepal earthquakes (fig.
1a) has been categorized as the Central Seismic
Gap by Khattri and Tayagi (1983) and has a high
probability for one or more M > 8 Himalayan
earthquakes in this century (Bilham et al., 1998).

Investigations carried out on active tecton-
ism for the past several decades have provided
vital information on the ongoing crustal defor-
mation and on recurrence of earthquakes in 
the Himalayas (Gansser, 1964; Nakata, 1972,
1975, 1989; Valdiya, 1984, 1989, 1992; Valdiya
et al., 1984, 1992; Nakata et al., 1990; Yeats
and Lillie, 1991; Yeats et al., 1992; Powers 
et al., 1998; Yeats and Thakur, 1998; Sukhija 
et al., 1999a,b; Wesnousky et al., 1999; Lave
and Avouac, 2000; Kumar et al., 2001; Oatney
et al., 2001). The ideal place to investigate active
tectonics is along the front of the Himalaya,
demarcating the present active tectonic bound-
ary between the Indian and Eurasian plates
(Nakata, 1972).

Bearing this in mind, emphasis was given
toward identification of active faults in the area
around Chandigarh and Pinjore Dun (Dun = val-
ley) located southeast of Kangra, which falls with-
in the meisoseismal area of the 1905 earthquake
(fig. 1a). Numerous new traces of active faults
were identified for the first time using CORONA
declassified satellite photos in the Himalayan foot-
hill zone along the HFF around Chandigarh, in
Pinjore Dun, along the piedmont zone of the
Lower Siwalik hill front and within the Lower
Tertiary hill range. The geometric pattern and dis-
tribution of the faults in this area reveal the pattern
of thrust and strike-slip faulting, striking parallel
to the principal structural orientation (NNW-SSE)
of the orogenic belt.

For detailed paleoseismic studies, a prelim-
inary trench investigation was carried out near
Chandigarh along a branching fault of the HFF
system. Here we summarize our preliminary find-
ings from the trench study. 

2.  General tectonic outline

The mighty Himalaya stretching east to
west over a length of 2500 km is a result of con-
tinental convergence and collision between
India and Eurasia. Ongoing convergence is esti-

mated as about 2000-3000 km since Late Cre-
taceous-Early Tertiary (Molnar and Tapponnier,
1977), at rates ranging between 44 mm and 60
mm/year (Minster and Jordan, 1978; Armijo et
al., 1989). Recent studies based on GPS meas-
urements show that India and Southern Tibet
converge at 20 ± 3 mm/year (Bilham et al.,
2001). This can be compared with the rates of
21 ± 3 mm/yr based on geological findings of
deformed terraces in Southern Nepal (Lave and
Avouac, 2000), 14 ± 4 mm/yr in Western Hima-
laya near Dehra Dun (Wesnousky et al., 1999);
11 ± 5 mm/yr and 14 ± 2 mm/yr across the
Himalayan Front in Dehra Dun and northwest
of Dehra Dun (Powers et al., 1998), and 15
mm/yr in Central Himalaya (Yeats and Thakur,
1998). It is believed that a convergence of about
300-400 km has been accounted for along the
Himalayan mountain belt (Gansser, 1977),
which involves the imbricate stacking of the
frontal portion of the underthrusting Indian
plate (LeFort, 1975). This is one fourth of the
total (i.e. 44 to 60 mm/yr) convergence between
the Indian and Eurasian plates (Minster and
Jordan, 1978), with the rest of the convergence
accommodated along the major strike-slip
faults of Central Asia in Tibet and Nepal (Mol-
nar, 1990; Avouac and Tapponnier, 1993).

Geological investigations suggest that the
Himalaya was built-up by the sliver of the
Indian continent that was overthrust to the
south (Gansser, 1964; LeFort, 1975). From the
beginning of convergence in Late Cretaceous
time, followed by the collision in the Middle
Eocene (50 Ma) along the Indus-Tsangpo
suture zone, the successive zones of deforma-
tion have progressively advanced or jumped
southward, resulting in faulting and folding
along the prominent structural features of the
Himalayan orogenic belt (Gansser, 1964;
Seeber and Armbruster, 1981; Lyon-Caen and
Molnar, 1983). These major tectonic features
(Indus-Tsangpo Suture Zone - ITSZ; Main
Central Thrust - MCT; Main Boundary Fault -
MBF; and Himalayan Frontal Fault - HFF)
have played a pivotal role in the structural and
topographic architecture of the Himalaya (fig.
1b). The MCT and MBT are considered to be
the sites of Cenozoic shortening along the
entire length of the Himalaya (Gansser, 1964;

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Active faults and related Late Quaternary deformation along the Northwestern Himalayan Frontal Zone, India



Valdiya, 1984), however, the present tectoni-
cally active boundary between the Indian and
Eurasian plates is marked by the HFF (Nakata,
1972, 1975, 1989), where active anticlines and
synclines are the surface manifestations of 
displacement on a buried décollement fault
(Yeats et al., 1992, 1997)

The present study area is characterized by
numerous NNW-SSE trending faults, part of
the MBF and HFF systems (fig. 2). In the north-
eastern part, subsidiary thrusts of the MBF sys-
tem, namely the Palampur./.Nahan thrust, Bar-
sar./.Gambhar thrust and Jawalamukhi thrust,
cut through the Tertiary succession (Valdiya,
1980). The Barsar thrust marks the boundary
between the Lower Siwalik hill range and the

Pinjore Dun, whereas the Jawalamukhi thrust
cuts the Middle and Lower Siwalik succession.
The southernmost edge of the study area is
marked by the HFF that delineates the bound-
ary between the detached complex folded-fault-
ed Upper Siwalik hills comprising molassic
sediments of Early Pliocene-Early Pleistocene
age and the undeformed succession of the Indo-
Gangetic plains.

3.  Geomorphology

The terrain around the study area can be
divided into four major geomorphic zones,
from north to south: 1) the uplands comprising

920

31°

76°

77°

Sutlej R.
G

ha
gg

ar

R
ive

r

Lesser Himalayan 
rocks

Subathus Nummulitic
limestone

M
e
so

zo
ic

a
n
d
 o

ld
e
r

Te
rt

ia
ry

Eocene

Murrees

Middle and Lower
Siwaliks

Upper Siwaliks

Alluvial Plains (IGP)
Recent River Terraces

Oligo-Miocene

Q
ua

te
rn

ar
y

Indo-G
angetic Plains

Bilaspur

Nahan

Simla

B
arsar T.

(G
am

bhar T.)

Jaw
a
la

m
u
kh

i T.

Palam
pur T./Nahan T.

H
IM

A
LAYA

N
 

P
lio

-P
le

is
to

ce
n
e

PIN
JO

R
E D

U
N

Study area

FAULT

20 km

N

Chandigarh

FRO
NTAL

Fig.  2. Generalized geological map of Northwestern Himalayan Front around Chandigarh and Pinjore (after
Gansser, 1964 and Valdiya, 1984).

Javed N. Malik and Takashi Nakata



Lower Siwalik./.Lower Tertiary rocks of the
Dagshai, Kasauli and Subathu Formations; 2)
a longitudinal alluvial fill-depression, Pinjore
Dun; 3) the isolated Upper Siwalik frontal
range, and 4) Indo-Gangetic plains (figs. 3 and 4).

Pinjore Dun is a typical «piggyback» basin.
It has been postulated that such basins or
depressions were formed as thrust fronts propa-
gated southward into the foreland, causing
numerous structural and depositional changes
and leading to subsequent development of new
«piggyback» basins behind the thrusts (Ori and
Friend, 1984; Burbank and Raynolds, 1988).
The Duns are the most common and conspicu-
ous feature of the foothill zone and are well
documented from the Kumaun, Panjab and
Nepal Himalaya. The sinuous nature of the
MBF has controlled the development and dis-
tribution of these intermontane-basins (Powers
et al., 1998).

The Pinjore Dun is 8 to 10 km wide extend-
ing parallel to Lower Siwalik./.Lower Tertiary
hills with altitude ranging from 600 to 1600 m
in the northeast and hogback ridges of Upper
Siwalik hills with altitude of 400 to 600 m in
the southwest (figs. 3 and 4). The Dun is about
45 km in length, merging farther north with the
Soan Dun. It is made up of thick alluvial fill 
of Late Pleistocene to Holocene age overlying
the Middle and Lower Siwalik succession.
These sediments represent debris deposits of coa-
lesced alluvial-fans that were brought down by
the Himalayan rivers, along with finer-grained
fluvial and lacustrine deposits. Due to recent
crustal movements, these sediments have been
dislocated along several tectonic lines parallel to
the Nahan thrust resulting in development of dif-
ferent levels of surfaces (Nakata, 1972).

Major antecedent streams emerging from
the Lower Siwalik./.Lower Tertiary hills in the
east flow perpendicular to the Pinjore Dun and
join the longitudinally-flowing major tributar-
ies of the Sutlej and the Ghaggar Rivers. Sirsa
River, a major tributary of the Sutlej River,
flowing northwest parallel to the Dun, is char-
acterized by a larger area of drainage as com-
pared to the southeast-flowing Jhajra River, a
tributary of the Ghaggar River. The divide of
the Sirsa and Ghaggar drainage systems is
located near Basdevpura at the southeastern end

of the Dun, an unusual geomorphic feature
(figs. 3 and 4). It is difficult to understand the
cause for the drainage diversion near village
Basdevpura. However, we assume that differen-
tial crustal uplift, along with the minor climatic
fluctuations in Pinjore Dun during the Late
Quaternary, was one of the causes for the diver-
sion.

The morphology of the various surfaces
and the sediment succession comprising main-
ly alluvial-fan debris made of cobble-boulder
size sandstone clasts ranging in size from 25 to
100 cm, along with fine-grained fluvial and
lacustrine sediments, suggests that initially the
Pinjore valley was aggraded under an alluvi-
alfan environment, and continued until the
stream flows were unconfined. Later, the chan-
nelized flows might have caused incision of the
alluvial-fan surfaces and contemporaneous ag-
gradation within the confined riverbanks,
resulting in formation of different terrace levels
all along their course. Distribution of terraces
varies along the different river valleys. The ter-
races in the southeastern part of Pinjore Dun
and along the Ghaggar gorge, where the Ghag-
gar River crosses the Upper Siwalik hills, have
been classified and described in detail by
Nakata (1972, 1989). Five terrace levels were
observed in the Pinjore Dun and along the
Ghaggar River. These are named the Ghaggar
surface, Kalak surface, Pinjore surface, Ko-
shallia surface and younger alluvial surface
(Nakata, 1972, 1989) (fig. 3).

The degree of dissection and the distribution
of these surfaces suggest that the Ghaggar 
surface is the oldest, followed by the Kalak,
Pinjore and Koshallia surfaces. Along the Ghag-
gar gorge, on the right bank of the Ghaggar
River, five terraces were recognized. Scattered
occurrences of terraces were also observed a-
long these streams in the upper reaches within
the Lower Siwalik./.Lower Tertiary hills, and are
classified as lower and higher upland terraces.
They are tentatively correlated with the Pinjore
and Koshallia surfaces of the Dun. The Pinjore
surface is one of the most widespread surfaces.
According to Nakata (1989), this surface must
have developed during the Last Glacial. How-
ever, a radiocarbon date of the oldest paleosol
from the Middle Gangetic Plain along the

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Active faults and related Late Quaternary deformation along the Northwestern Himalayan Frontal Zone, India



922

Javed N. Malik and Takashi Nakata

4 km

76°   50 76°   55

30°
50

30°
55

Chandigarh

Ghaggar surface

Kalka surface

Pinjore surface

Koshallia surface

Younger lower alluvial
surface

M1

M2

Fault scarplets (comb on 
the down thrown side)

Active fault trace (concealed)

Strike slip fault

Inferred active fault trace

Active folding

Active flexure

Direction of tilting

U
pper Siw

alik H
ills

Low
er Siw

alik/

Low
er Tertiary H

ills

Upper Siwalik Hills

H
FF

C
F

Trench site

HFF

P
G

F

P
G

F

P
G

F

B
T

B
T

B
T

B
T

TF

HFF

Chewag

Mandhala

Pinjore

Kalka
Taksal

Besdevpura

Gariran

S
irsa R

.
Raru Dora

Ko
sh

al
lia

 R
.

Jhajra R
.

BhanetJamli

Gunai

Kot Beja

Koti

Satiwala

Makhnu Majra

Kiratpu
r R.

Ram
naga

r R.

Nanakpur R.

Ba
la
d 

R.

Ratta R.

Baddi

G
h
a
g
g
a
r 

R
.

30°
45

Fig. 5

Ghatiwala

Fig. 7

Fig. 10

Fig. 12

Fig.  3. Map showing distribution of terraces and active fault traces along Northwestern Himalayan Foot Hill Zone
around Chandigarh and Pinjore Dun. CF - Chandigarh Fault; HFF - Himalayan Frontal Fault; PGF - Pinjore Garden
Fault; BT - Barsar Thrust and TF - Taksal Fault. Combs on the active faults indicate down thrown side.



923

Active faults and related Late Quaternary deformation along the Northwestern Himalayan Frontal Zone, India

40
0

N

0 4 km

76°  50´ 76°  55´

30°
40´

30°
45´

30°
50'

30°
55´

Chandigarh

G
ha

gg
ar

 R
.

Pinjore

Kalka Taksal

Mandhala

600

600

500

600
5
0
0

500

600

110
0

1000

800

10
00

14
00

16
00

1200

1100

1
0
0
0

8
0

0
900

Gunai

Chewag

1
0

0
0

8
0

0 90
0

900

1100

800

70
0

8
0
0

700

6
0
0

700

1100

10
00

1
0
0
0

600

50
0

400

40
0

4
0

0

50
0

400

400

50
0

50
0

50
0

40
0

50
0

400

500

40
0

600

400

6
0
0

7
0

0

500

500
600

400

4
0
0

400

500

70
0

4
0

0

Barotiwala

Kona

Satiwala

Besdevpura
Ghatiwala

Isharnagar

Mansa Devi

Nadah

Belwali

Saketri
Sukhna Lake

Makhnu Majra

Baddi

Gariran

Fig.  4. Detailed contour map of the area of fig. 3. Contour interval is 20 m, dashed lines show outline of major
as well as minor streams.



Ghaghra and the Gandak rivers (tributaries of
the Ganga River) gives an age of 10 ka, which
developed during a dry period (Mohindra, 1995),
and a terrace near Mohand town along the NW
Himalayan Front gives an age of 3663 ± 215
BP (Wesnousky et al., 1998). Also the OSL
dates of the alluvial-fan sediments from Dehra
Dun valley located 150 km southeast of the
study area suggests that the fan sedimentation
in Dehra Dun valley started at around 50 ka and
lasted up to 10 ka. After 10 ka, a thin prograd-
ing sequence was deposited due to uplift of the
fans (Singh et al., 2001). It is also suggested
that a major change in climate from a cold, dry
climate with strong seasonal variations prevail-
ing since 50 ka to warm and humid climate at
about 10 ka resulted in a change in deposition-
al processes from sediment gravity-flows to
braided streams (Singh et al., 2001). Singh et
al. (2001) have dated 4 levels of terraces
exposed along the left bank of the Yamuna
River: terraces YT4, 10.7 ± 2.2; YT3, 9.5 ± 2.3;
YT2, 8.9 ± 1.9 and YT1, 6.1 ± 1.2 ka. The geol-
ogy, geomorphology and tectonic setting of
Dehra Dun and Pinjore Dun are fairly similar.
Hence with the presumptions: 1) that the cli-
matic conditions might have remained the same
during Upper Pleistocene and Holocene in both
the areas; 2) alluvial fan sedimentation took
place in similar fashion in both the Duns by the
rivers flowing down the thrust front with a sim-
ilar provenance of Lower Siwalik hills, and 3)
also the tectonic scenario along the Himalayan
Front was similar, it can be envisaged that the
fan aggradation in the Pinjore Dun might have
initiated at around 50 ka and lasted up to 10 ka.
We have correlated the 4 levels of the Yamuna
River terraces with the 4-level of terraces ex-
posed along the Ghaggar River-Ghaggar, Kalka,
Pinjore and Koshallia terraces. This gives a ten-
tative age of 8.9 ± 1.9 ka for the Pinjore surface.
However, dating of the individual surface mate-
rial will help to confirm this chronology.

4.  Geometry and pattern of active faulting

Many prominent geomorphic features such
as warping and backtilting of fluvial and allu-
vialfan surfaces and southwest-facing fault scarp-

lets in the Quaternary succession were observed
along the active fault traces showing thrust move-
ment. Along the faults showing strike-slip move-
ment, lateral offsets of streams, offset of Qua-
ternary terraces, linear valleys running along the
fault and narrow deep gorges were the common
features observed (figs. 3 and 4). 

4.1. Active faulting along the Himalayan
Frontal Zone

The surface expression of the active fault
traces along the HFF is discontinuous (fig. 3).
However, it is presumed that the fault connects
in the subsurface but has not ruptured up to the
surface at all places along its length. The length
of individual active faults ranges between 2 and
10 km, with fault strikes between N25°W and
N-S.

Active faulting at places has vertically dis-
placed and warped the Late Pleistocene to Holo-
cene alluvial-fan succession, developing sharp
vertical scarplets facing southwest towards the
Gangetic plains (figs. 3 and 5). The most promi-
nent deformation along the HFF was observed
on the right bank of the Ghaggar River, about 5
km southeast of Chandigarh (Nakata, 1989),
named the Chandigarh Fault. Two parallel fault
traces were identified between Panchkula and
Mansadevi by satellite photo interpretation as
well as in the field (figs. 5 and 6). These faults
striking N25°W to N-S have uplifted the
Ghaggar, Kalka, Pinjore and Koshallia terraces,
resulting in fault scarps 15 to 38 m high trans-
verse to the Ghaggar River channel. The dis-
tance between the faults varies from 0.25 to 0.3
km. The faults are downthrown to the south-
west, superficially resembling a pattern of nor-
mal faulting. However, the topographic expres-
sion observed in the field and on satellite pho-
tos shows gentle warping of the surfaces near
the fault traces (fig. 6). To the north, these faults
follow the range front around Saketri village.
Here the Upper Siwalik hill range is marked by
a straight dissected front with well-developed
triangular facets. 

These active fault traces represent the younger
branching faults of the HFF system. These prob-
ably merge downward and northward into the

924

Javed N. Malik and Takashi Nakata



décollement; their geometry typically resem-
bles the imbricate faulting pattern seen in fold
and thrust belts (Burbank et al., 1992). Evi-
dence of the displacement of different terrace
levels along the branching faults, as well as the
maximum height of the scarp (38 m), suggests
continued tectonic movement through Late
Pleistocene to Holocene times. Due to lack of
age constraints on the respective surfaces, it is
difficult to estimate the timing of events.
However, if we consider that the Pinjore surface
was formed at around 8.9 ± 1.9 ka, then the
Koshallia and other younger surfaces might
have developed during the Late Holocene.
Later, these surfaces were subjected to periodic
uplift and deformation. The gentle warping of
the terraces near the fault line on the hanging
wall side suggests that the sediment succession
has been warped or folded in response to riding
over a bend in a fault with a steeper fault plane
near the surface. This type of geometry of de-
formation is commonly associated with the

thrusts that normally step up in the direction of
slip to a higher décollement or a ramp in a
décollement resulting in fault-bend folding as
defined by Suppe (1983). The straight faceted
range front is suggestive of ongoing tectonic
activity.

4.2. Active faulting in Pinjore Dun

The active fault traces extending across the
Pinjore Dun have vertically displaced and back-
tilted various surfaces along them (figs. 3, 4 and
7). The fault traces marked by the discontinu-
ous pattern belong to one single fault system
that extends laterally for more than 45 km
NNW-SSE, named here the Pinjore Garden
Fault. It is well exposed between the Pinjore
and Baddi town, along the Pinjore-Nalagarh
state highway. 

The Pinjore Garden Fault has displaced the
older Kalka surface and Pinjore surface along

925

Active faults and related Late Quaternary deformation along the Northwestern Himalayan Frontal Zone, India

Fig.  5. Stereo-pair of satellite photos showing active fault traces (marked by arrows) along the Himalayan Front
southeast of Chandigarh on the right bank of Ghaggar River (refer fig. 3 for location of active fault traces). Two
active fault traces (Chandigarh Fault) running parallel to one another between Panchkula and Mansadevi with
strikes N25°W to N15°E have vertically displaced and warped the Ghaggar, Kalka, Pinjore and Koshallia ter-
races comprising an alluvial-fan sediment succession of Late Pleistocene to Holocene age. Warping is clearly
seen near the fault line. Vertical uplift along the faults has resulted in 15 m to 38 m high southwest facing fault
scarplets. These scarps are transverse to the course of the Ghaggar River channel, representing the younger
branching out faults of the HFF system.



Javed N. Malik and Takashi Nakata

Fig.  6. View of Chandigarh Fault scarp near Mansadevi. Two southwest-facing fault scarps, marked by arrows show
vertically displaced flat alluvial-fan surfaces (Ghaggar and Kalka surface). The height of the lower scarp is about
15-16 m, and the higher one is about 38 m from the foreground in the Indo-Gangetic plains. The alluvial-fan sur-
face extends northeast for about 2-3 km. Trench site is marked on the left side of the photo. (Photo looking
towards northeast).

Fig.  7. Stereo-pair of satellite photos showing active fault traces cutting across the Pinjore Dun and along the Lower
Siwalik range front (refer to fig. 3 for location). The active faults are marked by arrows. The lower portion of the photo
shows vertically dislocated Pinjore and Kalka surfaces along Pinjore Garden Fault trending N25°W-N35°W. This
fault passes through the Mughal Garden. The Kalka surface near the fault line is warped and highly dissected com-
pare to the Pinjore surface. In the central portion of the photo, an active fault near Ghatiwala village has vertically dis-
placed and back-tilted the Pinjore surface. Prominent west- and southwest-facing scarp seen in the upper left of the
photo represents the southeastern extension of Barsar thrust and Taksal Fault, respectively.

926



with the younger surfaces giving rise to WSW-
and SW-facing fault escarpments. Average
height of the fault scarps ranges from 2 to 12 m,
although at some localities, the scarps are as
high as 15 to 16 m. Investigation around Pinjore
reveals that an active fault striking N35°W
passes through the Mughal Garden located
between the Koshallia and Jhajra rivers, where
the 12 m high «Big Step» marks the fault scarp
(fig. 8). This garden was constructed around
1600 A.D., using the fault scarp as the «main
step». The height of the scarp in the south is
about 8 to 10 m and extends further south up to
Isharnagar village on the left bank of Koshallia
River. Towards the north, the height of the scarp
is only 1.5 m to 2 m, and still farther north, the
scarp has a height of about 8 to 12 m near vil-
lage Ratpur. Here, along with the alluvial fan
deposits, the older Siwalik bouldery deposits
(Upper Siwaliks?) are also displaced. Farther
north, the fault passes through the village
Basdevpura uplifting and warping the sediments
of Kalka surface located between the Jhajra and
Sirsa rivers, which is presently marked by intensive
gully erosion (Nakata, 1972, 1989). Prominent

backtilting of the Pinjore surface was noticed
near Gariran village on the left bank of the
Kiratpur River, at Kona village between the
Surajpur and the Nanakpur rivers and at Makhu-
Majra village on the left bank of Ratta River. The
general tilt ranges from 6° to 8°.NE. Local warp-
ing or folding was recognized on the satellite
photos near Marhanwala, where the Pinjore sur-
face is tilted SW and NE. Long-term displace-
ment along this fault is well documented on the
left bank of the Balad River, where three levels
of terraces are displaced.

Two active faults were identified east of
Pinjore town, striking N-S and NNW-SSE near
Ghatiwala and Ramsar villages. These faults,
between the Koshallia and Jhajra rivers (figs. 3
and 7), have displaced the Pinjore surface, re-
sulting in a west-facing tectonic escarpment.
The active fault near Ghatiwala extends lateral-
ly for about 2 km. Maximum uplift of about 31
m along this fault can be seen in the central por-
tion (Nakata, 1989), uplifting the older Tertiary
succession along with the overlying 3 to 5 m
thick Quaternary deposits and backtilting the
surface 8° to 10° east (fig. 9). This fault dies out

Active faults and related Late Quaternary deformation along the Northwestern Himalayan Frontal Zone, India

Fig.  8. Active fault scarp used as main step (Big Step) at Mughal Garden in Pinjore town. The height of the
scarp is about 12 m and reduces to about 8-10 m in the south and 1.5-2 m in the north. This garden was con-
structed across this scarp around 400 years ago in 17th century. Arrow shows trace of active fault scarp.

927



northward into the floodplain of Jhajra River,
whereas to the south, it follows the range front.

The pattern of displacement along the
Pinjore Garden Fault System revealed by the
active fault scarps, developed on older as well
as younger surfaces, suggests that this fault sys-
tem has remained active. Backtilting and warp-
ing of the surfaces near the fault line are sug-
gestive of movement along a low-angle thrust
fault dipping northeast, similar to the pattern of
deformation observed in the Himalayan Frontal
portion along the Chandigarh Fault. Looking to
the intact structure of the Mughal Garden at
Pinjore, it is noteworthy that since the construc-
tion of this garden, no major earthquake has
struck this region, i.e. no movement has been
recorded along the Pinjore Garden Fault in the
last 400 years. Thus, it is presumed that strain is
accumulating along this fault, indicating high
seismic risk and potential for a large magnitude
earthquake in the future. The dislocation of the
Pinjore surface by two locally-developed paral-
lel faults east of Pinjore town according to

Nakata (1989) is the geomorphic expression of
imbricated thrusts branching from the Nahan
thrust. However, the present study reveals that
these faults are the manifestation of a branching
fault of the boundary fault or Barsar thrust. 

4.3. Active faulting along the Lower Siwalik
range front

The Lower Siwalik hill range trending
NNW-SSE marks the northeastern boundary of
the Pinjore Dun (figs. 3 and 4). To the south,
this range is flanked by the boundary fault,
probably the Barsar thrust of Valdiya (1980), a
branching fault of the MBF system. At some
localities along this thrust, there is little evi-
dence for active faults displacing the proximal
portion of the Late Pleistocene-Holocene allu-
vial fan sediment succession. The rest of the
portion along the hill range is marked by a
sharp contact with the plain showing a faceted
range front.

928

Javed N. Malik and Takashi Nakata

Fig.  9.  Back-tilting of Pinjore surface along with the underlying older Tertiary succession along active fault
(marked by arrow) near Ghatiwala village. Tilt is about 8°-10° east (view looking southwest).



Discontinuous geomorphic expression of the
active fault traces with strike N-S and NNW-SSE
suggests dislocation of the alluvial-fan surface
around villages like Kalka, Raru, Dhora, and be-
tween Mandhala and Satiwala (figs. 3 and 10). At
Kalka the active fault trace striking N-S has dis-
placed the fan surface (Pinjore surface), giving
rise to a 50 m high scarp. The scarp is located on
the right bank of the Jhajra River and extends lat-
erally for about 0.5 km. Three sub-parallel active
fault traces showing en échelon pattern were iden-
tified around Raru and Dhora villages, on the

right bank of Ramnagar River (figs. 3 and 10).
These faults striking NNW-SSE are characterized
by a SW-facing tectonic escarpments developed
by displacement of the fan surface. The average
length of these faults ranges between 0.25 and
0.6 km; the faults are about 0.3 km apart. The
height of the first scarp (on the way to Dhora
from Raru) is about 18 to 20 m; the second scarp
is 9 to 12 m high and the third more than 25 m
high. Farther north, the tectonic activity follows
the boundary of the range front marked by well-
developed triangular facets around Koti village.

Active faults and related Late Quaternary deformation along the Northwestern Himalayan Frontal Zone, India

Fig.  10.  Stereo-pair of satellite photos showing three sub-parallel active fault traces marked by typically en éche-
lon pattern around Raru and Dhora villages and prominent backtilting of alluvial fan surface near Mandhala vil-
lage (refer to fig. 3 for location). The height of the active fault scarp at Mandhala is about 20 m. These active
faults represent the Barsar thrust following the range front. Between Raru and Mandhala, the range front is
marked by straight dissected front with well-developed triangular facets.

929



The active faults exhibit a consistent left-stepping
pattern. However, no distinct lateral offset was
observed on the ground as well as on satellite pho-
tos. At Mandhala village, the active fault extend-
ing N-S for about 1.5 km has vertically uplifted
the fan surface, giving rise to a west-facing fault
scarp 20 m high and backtilting the surface
towards the east (figs. 3 and 11). The slope of the
surface is about 10° E. North of Mandhala, the
discontinuous traces of active faults displacing
fan sediments with west-facing fault scarplets are
seen as far as Satiwala village; no prominent
backtilting was noticed. 

The above-mentioned evidence suggests that
the active fault traces along the Barsar thrust are
the manifestation of reactivated tectonic activity
along the MBF that propagated southward along
these imbricated thrust faults. The vertical uplift
and associated backtilting suggest a similar pat-
tern of deformation observed along the Chandi-
garh Fault and Pinjore Garden Fault. The promi-
nent left-stepping pattern of the active faults
probably suggests some component of strike-slip
movement associated with the thrust faulting,
but due to lack of evidence, it is difficult to pin-
point the lateral offset on the surface.

4.4. Active faulting within the Lower 
Tertiary hills

In addition to the fault traces showing thrust
movement in the southwest portion of Pinjore
Dun, an active fault trace showing right-lateral

displacement of the Koshallia River channel by
250 m along the Nahan thrust near Taksal town
was observed by Nakata (1989). In the present
study, we were able to identify the extension of
this fault on satellite photographs as well as in the
field. The right-lateral strike-slip fault striking
NNW-SSE (N15°W) and extending for a distance
of about 20 km between Taksal and Chewag, is
here named the Taksal Fault (figs. 3, 4 and 7). 

This fault has right laterally displaced the
Lower Tertiary succession as well as younger
Quaternary fluvial terrace sediments. Lateral
offset of streams as well as fluvial terraces and
occurrence of narrow deep straight valleys are
common tectonic features observed along the
entire fault trace. Fault scarplets of 12 to 30 m
height facing ENE and WSW are the mani-
festation of the dip-slip movement. A maxi-
mum vertical displacement of about 50 to 56 m
was observed near Taksal on the left bank of
Koshallia River. The offsets of the streams are
not consistent all along the length of the fault
trace. Right-lateral offset of the minor as well
as the major streams varies from 250 m to 1350
m. Minimum displacement of 250 m and maxi-
mum of 1350 m has been observed around
Taksal town and around Kot Beja village, re-
spectively (figs. 3 and 12). No distinct branch-
ing pattern was observed along the fault, except
at Chewag village (figs. 3 and 12). The right-
stepping pattern near Chewag has resulted in
the formation of a small, elongated lenticular-
shaped pull-apart basin due to normal faulting
along the releasing bend of the faults. This

930

Javed N. Malik and Takashi Nakata

W E

Fig.  11.  Faulted and back-tilted surface representing proximal part of alluvial fan (Pinjore surface) along the range
front fault (Barsar thrust) at Mandhala. Height of the fault scarp is about 20 m. Arrow indicating fault scarp.
(View looking north).



small basin is about 230 m long in NNW-SSE
direction along the strike of the fault, and 30 m
wide in its center, narrowing to 11 m at the
northern end and 10 m at the southern end. The
sediment succession within the pull-apart basin
shows a typically horizontally stratified succes-
sion marked by alternating layers of fine- and
coarse-grained silty sand.

Displacement of the Lower Tertiary succes-
sion, Younger Quaternary fluvial terraces and
variable stream offsets suggests continued tec-
tonic movement from Late Tertiary to recent
times. The small pull-apart at Chewag is indica-
tive of a right stepover resulting in formation of
a dilatational secondary structure. The occur-
rence of this right lateral strike-slip fault parallel to
the principal structural trend (NNW-SSE) of the
Himalaya as well as the thrust fault to the west (i.e.
Barsar thrust, Pinjore Garden Fault and Chandi-
garh Fault) is a clear evidence of slip-partitioning
taking place between the reverse faults and the
strike-slip fault. This right-lateral strike-slip fault
marks a part of the MBF system and has been
due to the influence of ongoing oblique conver-

gence between India and Eurasia. Our observa-
tions are consistent with the observations made
by Mc Caffrey and Nabelek (1998) and Oatney et
al., (2001).

5.  Paleoseismic investigation along
Himalayan Front

At the base of a 16-20 m high fault scarp
striking N-S along Chandigarh Fault, a 14 m
long; 2 to 4 m deep and 4.5 m wide E-W trench
was dug to confirm the amount of displacement
and the pattern of faulting of the HFF system
(figs. 3, 5 and 13). The exposed sediment suc-
cession in the trench predominantly shows two
sedimentary units comprising poorly-sorted peb-
ble-cobble clasts with occasional occurrence of
boulders and a medium- to coarse-grained mas-
sive sandy unit. 

Exposed sediments in the trench were sub-
divided into five facies (fig. 13). Unit OCd rep-
resents older channel fill deposits composed of
loose matrix-supported pebble-cobble-boulders

931

Fig.  12.  Stereo-pair of satellite photos showing right-lateral stream offsets along NNW-SSE trending Taksal Fault
between Banet and Chewag villages (refer to fig. 3 for location). The fault has displaced along it Tertiary strata
as well as Quaternary sediments. Along with the streams, younger terraces are seen displaced right laterally
along the fault. Right stepping along the fault has resulted in formation of small pull-apart near Chewag village.

Active faults and related Late Quaternary deformation along the Northwestern Himalayan Frontal Zone, India



of sandstone of Dagshai, Kasauli and Subathu
formations: the matrix is mainly fine gravel,
coarse sand and silt. Units S1 and S2 are the
massive medium to coarse sand facies, unit Cd
is a channel fill deposit made of pebbles and
cobbles with a sandy matrix, and unit Cb is a
channel bar made of comparatively finer gravel
clasts seen in OCd and Cd facies, with matrix of
medium-fine sand, silt and clay. 

Only one fault strand (F) was identified,
which has displaced OCd, S1 and Cd exposed
in the eastern portion of the trench. Total dis-
placement of about 3.5 m was inferred along a
low-angle thrust fault with dip ranging from
20° to 46° east at a depth of 4 m below the pres-
ent surface. The fault is marked by an angle of
dip of about 46° near the surface in the western
portion of the trench and a lower angle of dip of
20° towards the east. The movement from east
to west along this fault has resulted in slight
deformation within the channel deposit, re-
vealed by the pattern of clast fabric marked by
reoriented gravels, resembling folding near the
tip of the fault plane.

Due to lack of numerical age constraints, it
is difficult to pinpoint the time of this event.
However, looking to the displacement along
fault (F.) cutting the unit Cd, the youngest unit,
and an insignificant cover of well developed
soil, it is suggested that this event is the latest
event in this area along the Chandigarh Fault.
The net displacement along the fault (F.) of
about 3.5 m indicates one single large paleo-
earthquake. If we consider that the 3.5 m is the
maximum displacement during one event, then
the empirical relationship of Wells and Cop-
persmith (1994), suggests Mw 7 for this event.
Taking the average angle of the fault (25°) gives
a vertical displacement of about 1.5 m and a
horizontal shortening of about 3.2 m for one
large magnitude event. 

6.  Discussion and conclusions

The present study along the Northwestern
Himalayan Frontal Zone around Chandigarh
and Pinjore Dun has helped in understanding

932

Javed N. Malik and Takashi Nakata

S2

S1

Cd

OCd

F

Cb

S1

F
F

W E

Fig.  13.  North wall of E-W trending trench at the base of Chandigarh Fault scarp near Mansa Devi (refer to
figs. 3 and 5 for location). Low-angle thrust fault with dip ranging from 20° to 46° east has displaced poorly-
sorted gravelly unit representing old channel trough and massive sand units by 3.5 m. In the lower portion of the
trench, the fault plane is distinctly marked by 10 to 12 cm thick crushed zone or brecciated zone comprising
angular clasts that were crushed and dragged along the fault during the movement from the underlying unit.
Aligned discoidal pebbles along their elongated axes mark the fault passing through the channel deposit, which
are oriented parallel to the fault plane contact. String on the wall shows grid of 1 m. Cd - channel deposit; S1
and S2 massive sand deposit; Cb - channel bar; OCd - older channel deposit.



the ongoing crustal deformation and its rela-
tionship with the plate motion along the Indo-
Eurasian plate boundary. The sense of move-
ment along these fault traces identified on the
basis of geomorphic as well as field investiga-
tions indicates thrust and strike-slip faulting.
Overall pattern and geometry of active fault
traces identified along the Himalayan Front,
within Pinjore Dun and along the Lower
Siwalik range front suggest that the ongoing
tectonic deformation within the Himalaya has
propagated southward along the various branch-
ing faults that belong to the major fault systems
like the MBF and HFF. These branching faults
are the manifestation of imbricated thrust
faults in this region. The displacement of vari-
ous terraces along these branching faults
marked by vertical scarplets with maximum
height ranging between 12 and 56 m suggests
continued tectonic movement through Late
Pleistocene to Holocene times and cumulative
slip along the Chandigarh Fault, Pinjore
Garden Fault and Barsar thrust. Gentle warp-

ing of the terraces near the fault line on the
hanging wall and backtilting suggests fault-
bend folding. 

The «Big Step» of Pinjore Mughal Garden
representing the active fault scarp suggests that
no movement has been recorded along the
Pinjore Garden Fault since the construction of
this garden 400 years ago. Thus, this fault has a
high seismic hazard for a large magnitude
earthquake in the future. The occurrence of the
right-lateral strike-slip Taksal Fault striking
NNW-SSE in the northeastern side of the thrust
faults is a clear evidence of slip-partitioning be-
tween reverse faults and a strike-slip fault.
Seven streams showing prominent lateral offset
along the fault were taken into account to cal-
culate offset ratio (a = D/L), where D is the
amount of stream offset along fault and L is
upstream length of the displaced stream
(Matsuda, 1966) (fig. 14). This gives an offset
ratio of about 0.28. A relationship between
long-term slip rate (S) along lateral slip of
fault and offset ratio (a = D/L) has been rough-

933

Active faults and related Late Quaternary deformation along the Northwestern Himalayan Frontal Zone, India

Fig.  14.  Relationship between amounts of stream offset along the fault and upstream length from the fault trace
of the Taksal Fault between Banet and Chewag.



ly calculated as S (m/1000 years), i.e. 10 a
(Matsuda, 1975). This relationship gives a slip
rate along Taksal Fault of about 2.8 mm/yr.
The strike of Taksal Fault almost parallel 
to the principal structural trend (NNW-SSE) 
of the arcuate Himalayan belt as well as the
thrust faults is indicative of change in the di-
rection of maximum principal compressive
stress axis from N-S in the Eastern Himalaya
to NE-SW in the Western Himalayan Frontal
Zone (Nakata et al., 1990). This also explains
the phenomenon of ongoing oblique conver-
gence of the Indian plate (Nakata et al., 1990).
However, the model on the basis of small-cir-
cle approximation with radius 1696 ± 55 km 
of Himalayan arc suggests that the regional
convergence vector and stress fields are radial
to the arc (Bilham et al., 1998; Bendick and
Bilham 2001). McCaffrey and Nabelek (1998)
suggested that active tectonics of the Himalaya
and the southern half of Tibet show a strong re-
semblance to the subduction style at the curved
oceanic trenches such as Sumatra, with oblique
convergence and occurrence of trench-parallel
strike-slip and extension. They also suggested
that radial vergence in earthquake slip vector
along the front, east-west extension in Southern
Tibet, and right-lateral slip on the Karakoram
Fault are on account of the basal shear caused
by the oblique sliding of Indian plate along the
arcuate plate boundary. Also recent studies
around Dehra Dun valley suggest that strike-
slip movement on the Trans-Yamuna active
fault system may be related to arc-parallel lat-
eral translation of the Karakoram fault block
and east-west extension of the Southern Tibet
block, in response to the oblique convergence
between the Indian and Eurasian plates (Oatney
et al. 2001). Our observations are consistent
with the model suggested by McCaffrey and
Nabelek (1998) and the observation made by
Oatney et al. (2001). This also explains the
westward reduction of convergence rates from
Nepal to India (Yeats and Thakur, 1998) and
phenomenon of slip partitioning between
thrust and strike-slip faults. 

A preliminary trench investigation at the
base of the Chandigarh Fault scarp revealed
total displacement of 3.5 m along a low-angle
thrust fault with variable dip of 20° to 46°

northeast, suggesting a large magnitude (Mw 7)
prehistoric earthquake. Presuming an average
dip of the fault of 25°, the vertical component
of displacement is about 1.5 m, and horizontal
crustal shortening is about 3.2 m for one event.
It is quite logical that the Chandigarh Fault has
displaced various surfaces along it such as the
Ghaggar, Kalka, Pinjore and Koshallia sur-
faces. It is envisaged that the fan aggradation
within the Pinjore Dun initiated at around 50
ka and lasted up to 10 ka, and the Pinjore sur-
face gives an age of 8.9 ± 1.9 ka. Taking into
account the age and the height of the Pinjore
surface along the Chandigarh Fault ranging be-
tween 20 and 25 m, the displacement of 3.5 m
per event with dip of the fault 25° gives a slip
rate of about 6.3 ± 2 mm/yr, a rate of horizon-
tal shortening about 5.8 ± 1.8 mm/yr and
recurrence of faulting 555 ± 118 years along
the Himalayan Frontal Fault. A recent paleo-
seismic investigation along the Black Mango
tear fault in the same region has also revealed
evidence of two large surface rupture earth-
quakes during the past 650 years, subsequent
to 1294 A.D. and 1423 A.D. and another at
about 260 A.D. (Kumar et al., 2001) Also
paleoseismic investigations along the Sirmu-
rital Fault in Dehra Dun valley on the basis of
two colluvial wedges suggest that two earth-
quakes have struck this region in the last 1000
years (Oatney et al., 2001).

The direct estimates of the convergence
rate along the HFF based on geological find-
ings suggest shortening rate of 11 ± 5 mm/yr
and 14 ± 2 mm/yr across Dehra Dun and north-
west of Dehra Dun respectively (Powers et al.,
1998); horizontal shortening of 11.9 ± 3.1
mm/yr, and a slip rate along fault of 13.8 ±
3.16 mm/yr near Dehra Dun (Wesnousky 
et al., 1999). The offset of Late Pleistocene
and Holocene terrace deposits indicates a con-
vergence rate of about 21 ± 3 mm/yr in Nepal
(Lave and Avouac, 2000), and the investiga-
tion along the Black Mango tear fault suggests
fault slip and crustal shortening of 9.62.+7–3.5
mm/yr and 8.42.+7–3.6 mm/yr (Kumar et al.,
2001). These rates are consistent with GPS
measurements that give a convergence rate of
20 ± 3 mm/yr. This suggests that our results
are consistence with the results of the above

934

Javed N. Malik and Takashi Nakata



mentioned workers, because the slip rate of
about 6.3 ± 2 mm/yr which we got along the
Chandigarh Fault shows the minimum slip
rate. Trench investigations along the other
active faults, viz., the Pinjore Garden Fault,
Barsar thrust and Taksal Fault will be able to
give a complete summary of the slip along
these faults in this region.

Our investigation has thrown considerable
light on the occurrence of active faults and evi-
dence of large magnitude pre-historic earth-
quake in this area. The concentration of active
faults and their geographic location clearly
show that these faults pass through or are near
populated areas such as Chandigarh, through
Pinjore Dun where lie many small towns and
villages. Similar is the case along the pied-
mont zone and in the hill range where traces of
active faults pass through small villages. It is
envisaged that these areas fall under a high
seismic hazard zone and the active faults are
the biggest threat if large magnitude earth-
quake struck this region in future. Detail paleo-
seismic studies are very much important to
build up a long-term earthquake database of
large magnitude prehistoric events. Our find-
ing will play a key role and path for future
detailed studies and towards evaluating seis-
mic hazard of this region.

Acknowledgements

We are thankful to both the referees for
giving constructive and valuable comments
which helped us in improving our text and dis-
cussion part. JNM gives his due respect and
gratitude to Prof. Robert Yeats for giving
invaluable suggestions and encouragement
during this study. The financial support pro-
vided by JSPS (Japan Society for Promotion
of Science), Tokyo, Japan is gratefully
acknowledged. JNM is grateful to JSPS for
providing him a post-doctoral fellowship for
the year 1999-2001 (ID No. P99074), to
undertake this work in Japan at Department of
Geography, Hiroshima University under the
guidance of Prof. Takashi Nakata. Funding
provided to JNM by DST (vide project No.
SR/FTP/ES-46/2001) is duly acknowledged.

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Javed N. Malik and Takashi Nakata