36Bilham.qxd


839

ANNALS  OF  GEOPHYSICS, VOL.  47, N.  2/3, April/June  2004

Key  words India  –  earthquakes  –  history

1. Introduction

Throughout the invasions of different ethnic
and religious entitites in the past two millennia the
Indian subcontinent has been known as Hindoost-
an, Hindustan or India in recognition of its unique
isolation imposed by surrounding mountains and
oceans. The northern, eastern and western moun-
tains are the boundaries of the Indian plate. The
shorelines are the echoes of ancient plate bound-
aries. Only in recent time have the separate nations
of Pakistan, India, and Bangladesh subdivided the
continental expression of the Indian Plate. In this

article I shall use the term India to signify both the
Indian tectonic plate and the subcontinent of India.

Perhaps the most disappointing observation is
that despite a written tradition extending beyond
1500 B.C. we know very little about Indian
earthquakes earlier than 500 years before the
present, and records are close to complete only
for earthquakes in the most recent 200 years. This
presents a problem for estimating recurrence in-
tervals between significant earthquakes, the holy
grail of historic earthquake studies. Certainly no
repetition of an earthquake has ever been recog-
nized in the written record of India and the Hi-
malaya, although great earthquakes in the Hi-
malaya should do so at least once and possibly as
much as three times each millennium. The strain
rate within the Indian plate is observed to be less
than 3 ns/yr (Bilham and Gaur, 2000) and the re-
newal time for earthquakes in the sub-continent
may exceed many thousands of years, rendering
it unlikely that earthquakes will have repeated
during the time of written records.

Earthquakes in India and the Himalaya:
tectonics, geodesy and history

Roger Bilham
Cooperative Institute for Research in Environmental Sciences (CIRES) and Geological Sciences,

University of Colorado, Boulder, CO, U.S.A.

Abstract
The record of earthquakes in India is patchy prior to 1800 and its improvement is much impeded by its disper-
sal in a dozen local languages, and several colonial archives. Although geological studies will necessarily com-
plement the historical record, only two earthquakes of the dozens of known historical events have resulted in sur-
face ruptures, and it is likely that geological data in the form of liquefaction features will be needed to extend
the historical record beyond the most recent few centuries. Damage from large Himalayan earthquakes record-
ed in Tibet and in Northern India suggests that earthquakes may attain M = 8.2. Seismic gaps along two-thirds
of the Himalaya that have developed in the past five centuries, when combined with geodetic convergence rates
of approximately 1.8 m/cy, suggests that one or more M = 8 earthquakes may be overdue. The mechanisms of
recent earthquakes in Peninsular India are consistent with stresses induced in the Indian plate flexed by its col-
lision with Tibet. A region of abnormally high seismicity in western India appears to be caused by local con-
vergence across the Rann of Kachchh and possibly other rift zones of India. Since the plate itself deforms little,
this deformation may be related to incipient plate fragmentation in Sindh or over a larger region of NW India.

Mailing address: Dr. Roger Bilham, Cooperative Insti-
tute for Research in Environmental Sciences (CIRES) and
Geological Sciences, University of Colorado, Boulder, CO
80309-0399, U.S.A.; e-mail:Roger.Bilham@colorado.edu



840

Roger Bilham

In contrast, trench investigations indicate
that faults have been repeatedly active both on
the subcontinent (Sukhija et al., 1999; Rajen-
dran, 2000) and within the Himalayan plate
boundary (Wesnousky et al., 1999). The exca-
vation of active faults and liquefaction features
is likely to play an important role in extending
the historical earthquake record of Indian earth-
quakes in the next several decades.

A feature of Indian earthquakes for which
numerical deformation data have recently been
exhumed is that these data, once analyzed, have
required substantial revision of earlier in-
formed, but speculative, interpretations of the
causal mechanisms of historic earthquakes. Ge-
odetic data have surfaced for the 1819, 1881,
1897 and 1905 earthquakes that have largely
negated the conclusions of many learned arti-
cles. This obviously raises a cautionary flag:
that conclusions concerning felt reports about
earthquakes in history and prehistory have lim-
ited value in interpreting subsurface structure.

I first give a brief overview of Indian tecton-
ics. I then describe catalogues and data that char-
acterize Indian earthquakes, and conclude with a
number of case histories that discuss some of the
important problems that have surfaced in studies
of Indian earthquakes, and that may be resolved
by the discovery of further data. I conclude with a
discussion of our current understanding of seis-
mic hazard in India and the Himalaya.

2. Tectonic setting of India

India is currently penetrating into Asia at a
rate of approximately 45 mm/yr and rotating
slowly anticlockwise (Sella et al., 2002). This ro-
tation and translation results in left-lateral trans-
form slip in Baluchistan at approximately 42
mm/yr and right-lateral slip relative to Asia in the
Indo-Burman ranges at 55 mm/yr (fig. 1). Be-
cause of complexities in the structural units at its
northern, western and eastern boundaries these
velocities are not directly observable across any
single fault system. Deformation within Asia re-
duces India’s convergence with Tibet to approxi-
mately 18 mm/yr (Wang et al., 2001), and be-
cause Tibet is extending east-west, convergence
across the Himalaya is approximately normal to

the arc. Arc-normal convergence across the Hi-
malaya results in the development of potential
slip available to drive large thrust earthquakes be-
neath the Himalaya at roughly 1.8 m/cy, hence
earthquakes associated with, say, 6 m of slip can-
not occur before the elapse of an interval of at
least three centuries (Bilham et al., 1997).

Slip across the 150-300 km wide plate
boundary between Asia and India in Baluchistan
is apparently partitioned between thrust and
strike-slip components. For example, the 1931
Mach Ms = 7.3 earthquake was associated with 1
m of NW directed reverse slip on a fault that may
have extended entirely through the crust. It was
followed 4 years later by the Ms = 7.7 strike-slip
Quetta earthquake on a subparallel fault less than
150 km NW of the Mach event. The Mach event
slipped in a sense that effectively unclamped the
subsequent Quetta earthquake (Ambraseys and
Bilham, 2003a). Slip on the Chaman fault further
to the north in Afghanistan in the past century, and
possibly for a longer period, has been much less
than 42 mm/yr according to seismic moment sum-
mation of observed seismicity (Ambraseys and
Bilham, 2003b). Although this may be the result of
minor deformation in the northern Afghan moun-
tains, or unreported creep on the Chaman fault, it
is quite possible that the northern Chaman fault
system may be overdue for a large earthquake.

Slip in the IndoBurman ranges is also accom-
panied by strike-slip and thrust seismicity and al-
though no recent large earthquakes have occurred
on land, the north-south Sagaing fault system is
clearly strike-slip and the Indo-Burman ranges to
its west the result of distributed east-west conver-
gence. Near the Andaman Islands slip is parti-
tioned between thrust earthquakes to the west and
beneath islands, and strike-slip faulting on the
North Andaman fault to their east (Curray et al.
1979; 1982; Ortiz and Bilham, 2003)

GPS measurements in India reveal that con-
vergence is less than 5 ± 3 mm/yr from Cape
Comorin (Kanya Comori) to the plains south of
the Himalaya (Paul et al., 2001). Hence the In-
dian Plate should not be expected to host fre-
quent seismicity. However, the collision of India
has resulted in flexure of the Indian Plate (Bil-
ham et al., 2003). The wavelength of this flexure
is of the order of 650 km and results in an ap-
proximately 450-m-high bulge near the central



841

Earthquakes in India and the Himalaya: tectonics, geodesy and history

Fig.  1. Schematic views of Indian tectonics. Plate boundary velocities are indicated in mm/yr. Shading indi-
cates flexure of India: a 4 km deep trough near the Himalaya and an inferred minor (40 m) trough in south cen-
tral India are separated by a bulge that rises approximately 450 m. Tibet is not a tectonic plate: it extends east-
west and converges north-south at approximately 12 mm/yr. At the crest of the flexural bulge the surface of the
Indian plate is in tension and its base is in compression. Locations and dates of important earthquakes mentioned
in the text are shown, with numbers of fatalities in parenthesis where known. With the exception of the Car Nico-
bar 1881, Assam 1897 and Bhuj 2001 events, none of the rupture zones of major earthquakes are known with
any certainty. The estimated rupture zones of pre-1800 great earthquakes are shown as unfilled outlines, where-
as more recent events are filled white.



842

Roger Bilham

Indian Plateau, corresponding to the outer rise
of an oceanic collision. Normal faulting earth-
quakes occur north of the flexural bulge (e.g.,
possibly on 15 July 1720 near Delhi) and deep
reverse faulting occurs beneath its crest (e.g., the
M = 6.3 21 May 1997 Jabalpur earthquake).
Shallow reverse faulting occurs south of the
flexural bulge where the Indian plate is de-
pressed (e.g., the M = 6.3 29 September 1993
Latur earthquake, fig. 1).

The Indian plate is bent downwards by 4-6
km beneath the southern edge of the Himalaya
attaining depths of 18-20 km beneath the south-
ern edge of Tibet (fig. 1). Stresses within the
plate vary from tensile above the flexed neutral-
axis to compressional below it. Where no in-
plane end-loading prevails the position of the
neutral axis lies theoretically half way through
the thickness of the elastic plate. Since in-plane
stresses of the order of 500 bars exist (necessary
to maintain the height of the Tibetan Plateau)
this effectively means that the neutral axis rises
above the plate south of the crest of the central
Indian bulge. The neutral axis descends into the
plate just north of the bulge where it is initially
flexed downward. The axis would descend to a
path a little above half-way through the plate
were it perfectly elastic, since the flexural
stresses are much larger than the weak in-plane
collisional stresses. However, normal-faulting
in the upper surface of the plate near the
Ganges Trough weakens the top surface of the
plate thereby lowering the neutral axis, and
plastic conditions near the base of the plate both
raise the neutral axis, both thinning the effec-
tive elastic thickness and shifting the neutral
axis to an unknown depth. Eventually, when
sufficient focal mechanisms are available from
the descending plate, it may be possible to iden-
tify the location of the neutral axis from the ab-
sence of earthquakes near the axis, and from the
difference in mechanisms above and below it.

The presence of both flexural stresses and
plate-boundary slip permits all mechanisms of
earthquakes to occur beneath the Lesser Hi-
malaya (fig. 1). At depths of 4-18 km great
thrust earthquakes with shallow northerly dip
occur infrequently that permit the northward
descent of the Indian plate beneath the subcon-
tinent. Earthquakes in the Indian plate beneath

these thrust events range from tensile just below
the plate interface, to compressional and strike-
slip at depths of 30-50 km (e.g., M = 6.6 20 Au-
gust 1988, Udaypur).

A belt of microearthquakes and moderate
earthquakes beneath the Greater Himalaya on
the southern edge of Tibet indicates a transi-
tion from stick-slip faulting to probable aseis-
mic creep at around 18 km. This belt of mi-
croseismicity defines a small circle with ra-
dius 1695 km (Seeber and Gornitz, 1983; Ben-
dick and Bilham, 2001). Seismicity in Tibet is
largely shallow and is either normal faulting or
strike-slip faulting.

The flexural geometry of the Indian plate is
manifest as a standing wave fixed relative to
southern Tibet. Stresses in the plate vary with
time because the Indian plate streams slowly
though this flexural wave, bringing points
within India towards, or away from, compres-
sional or tensile failure. It is for this reason that
the earthquakes that occur throughout central
and northern India appear to have no distinc-
tive spatial pattern. The flexural stresses are
significantly larger than the in-plane stresses
needed to sustain the elevation of the Tibetan
Plateau, but their change with time is slow
(mbar/yr). Despite this their spatial change is
large (up to 2 bars per km northeastward) and
this results in an important imposed south-north
spatial variation in stress (Bilham et al., 2003).
Stress changes of less than 1 bar are known to
trigger earthquakes. Although stresses through-
out most of NE India are everywhere close to
failure, the triggering of earthquakes occurs
partly from the movement of India through the
flexural stress field, and partly from local stress
perturbations caused by other tectonic, erosion-
al or dynamic processes.

3. Historical data sources and catalogues

Early earthquakes described in mythical
terms include extracts in the Mahabharata
(≈ 1500 B.C.) during the Kurukshetra battle
(Iyengar, 1994), and several semi-religious
texts that mention a probable Himalayan earth-
quake reputed to have occurred during the time
of enlightment of Buddha ca. 538 B.C.



843

Earthquakes in India and the Himalaya: tectonics, geodesy and history

earthquake because it is alleged to have been
followed by three years of aftershocks, but the
absence of reports from other locations renders
this of little value in estimating its rupture di-
mensions or magnitude. Similarly the arrival of
Vasco de Gama’s fleet in 1524 coincided with a
violent sea-quake and tsunami that caused alarm
at Dabul (Bendick and Bilham, 1999).  Note that
this Portuguese port at latitude 17°34’ on the
Malabar Coast is unrelated to Debil above. This
could have been a local event, but since it was
not reported onshore it could have been the
tsunami from a remote earthquake that occurred
along the Makran or Gujarat coastlines. Such
accounts are thus of fragmentary value in quan-
tifying earthquake locations and sizes.

The emergence and disappearance of
coastal tracts has sometimes been ascribed to
earthquakes. A storm near Cochin in 1341
caused an island to emerge, but inspection sug-
gests this to be a common accretional feature of
storms along the Malabar Coast (Bendick and
Bilham, 1999). An island that sank in 1769
south of Chittagong (Oldham, 1883) may have
undergone lateral spreading at the time of sig-
nificant earthquake near there (Seeber, pers.
comm., 2003).

In the mid 19th century some of these frag-
mentary data were collected successively in
summaries of earthquakes by Mallett, Baird-
Smith and Oldham, but there followed more
than a century of archival neglect when little

Archeological excavations in Sindh and Gu-
jarat suggest earthquake damage to now aban-
doned Harrappan cities. A probable earthquake
around 0 A.D. near the historically important
city of Dwarka is recorded as a zone of lique-
faction in archeological excavations of the an-
cient city (Rajendran et al., 2003). The town of
Debal (Dewal, Debil, Diul Sind or Sindi) near
the current site of Karachi was alleged to have
been destroyed in 893 A.D. (Oldham, 1883),
but until recently accounts of its collapse and
inundation were considered too vague to be tak-
en seriously. Rajendran and Rajendran (2002)
present a case that the destruction of Debil was
caused by an earthquake linked to the same
fault system responsible for the 1819 and 2001
Rann of Kachchh earthquakes, however, Am-
braseys (2003) notes that Oldham’s sources re-
fer to Daibul (Dvin) in Armenia, and that lique-
faction 1100 years ago in western India must be
attributed to a different earthquake. Figure 2
shows the location of Debil west of the Indus
delta in a 1690 map drafted by A.D. Winter.
Other maps place it within the distributaries of
the Indus. Yule and Burnell (1903) describe De-
bil’s 1000-year-long history, prior to its effec-
tive disappearance from accounts within a cen-
tury of a second earthquake in its vicinity in
1668 (Oldham, 1883; Ambraseys, 2004).

A single paragraph describes a massive
earthquake in the Kathmandu Valley in 1255
(Wright, 1877), which may have been a great

Fig.  2. Maps in 1690 and 1740 show Debil near the current location of Karachi. Other maps show it on a dis-
tributary of the Indus. An earthquake occurred there in 1668 and another is alleged by Thomas Oldham (1883)
to have occurred in 893 but the event he invokes occurred in an Armenian town with a similar name (Ambraseys,
2004). The city is last mentioned in the 18th century (Yule et al., 1903)



844

Roger Bilham

new information surfaced. The seismicity of the
sub-continent has been summarized in compila-
tions by Chandra (1977), Srivastava and Ra-
machandram, (1985), Rao and Rao (1984) and
by Khattri (1987). Recent interest in early
earthquakes have engaged historians in India
and elsewhere in a systematic search through
Urdu, Arabic, Tibetan, Chinese, Nepalese and
European languages.

Two important publications summarize re-
cent findings: Iyengar and Sharma (1998) re-
port accounts in Arabic, Sanskrit and Urdu
sources and Ambraseys and Jackson (2003)
provide new data from Tibet and recently col-
lated colonial records. Data presented in these
publications remain sparse but provide a skele-
tal framework of events on which to build a fu-
ture quantitative assessment of historic Indian
earthquakes as new documents surface.

A list of Indian earthquakes is to be found
in Bapat et al. (1983) but this contains numer-
ous entries that have been included uncritically
from secondary sources, and for these reasons
can be misleading. Similarly, entries in the un-
critical listing of Dunbar et al. (1992) require
careful evaluation before use. A useful and eas-
ily accessible compilation of information and
resources for the study of Indian earthquakes is
a webpage maintained by Stacey Martin,
http://asc-india.org/menu/gquakes.htm. Relo-
cated instrumental earthquakes are listed by
Engdhal et al. (1998).

An important recent realization is that a se-
quence of significant earthquakes occurred
throughout the west Himalaya in the 16th centu-
ry. The sequence started in Kashmir in 1501,
followed by two events a month apart in
Afghanistan and the central Himalaya, conclud-
ing with a large earthquake in Kashmir in 1555.
The central Himalayan 1505 earthquake may
have been Mw ≥ 8.2 based on its probable rup-
ture area. It destroyed monasteries along a 500
km segment of southern Tibet, in addition to de-
molishing structures in Agra and other towns in
northern India (Jackson, 2002; Ambraseys and
Jackson, 2003; Bilham and Ambraseys, 2004).

A Himalayan earthquake that damaged the
Kathmandu Valley in 1668 is mentioned briefly
(a single sentence) in Nepalese histories but as
with events in 1255 and 1408 no details are giv-

en (Chitrakar and Pandey, 1986). Earthquakes
in the 18th century are poorly documented. An
earthquake near Delhi in 1720 caused damage
and apparent liquefaction but little else is
known of this event (Kahn, 1874; Oldham,
1883). This event, from its location, could have
been a normal faulting event, but because of the
absence of damage accounts from the Hi-
malaya it may have been a Himalayan earth-
quake. In 1713 a severe earthquake damaged
Bhutan and parts of Assam (Ambraseys and
Jackson, 2003).

Thirteen years later, in September 1737, a
catastrophic earthquake is alleged to have oc-
curred in Calcutta. This is the most devastating
earthquake to be listed in many catalogues of
Indian (and global) earthquakes but is actually a
storm surge that resulted in numerous deaths by
drowning along the northern coast of the Bay of
Bengal. The handwritten ledgers of the East In-
dia Company in Bengal detail storm and flood
damage to shipping, wharves, warehouses and
dwellings in Calcutta with an estimate of 3000
deaths by drowning (Bilham, 1994). Calcutta’s
population at the time was approximately
30 000. A figure of 300 000 fatalities is often as-
cribed to this «fake quake» for which earth-
quake shaking was probably invoked in news
reports as a metaphor for destruction, a possible
description of the buffeting accompanying ex-
treme wind velocities. The spire of St. Annes
church, Calcutta, was blown down by these
winds, but the masonry church survived. An ap-
proximate 10% increase in burials is recorded in
its churchyard for 1737, an increase in deaths
that year by fewer than two dozen. Although the
death-toll from drowning along the coast of
southern Bengal was presumably greater than
the official estimates in Calcutta, the fatality
count of 300 000 is repeated only in accounts
published in monthly magazines and newspa-
pers in Europe, and is not substantiated by offi-
cial documents from any of the several adminis-
trative centers then functioning in Bengal.

India in the early 19th century was as yet
incompletely dominated by a British colonial
administration. Remote administrators in dis-
tant parts of the India subscribed to newspapers
and wrote verbose and sometimes extensive de-
scriptions of their experiences which were typ-



845

Earthquakes in India and the Himalaya: tectonics, geodesy and history

Fig.  3. Oldham, father and son, were both geologists in India. Thomas Oldham (left) compiled the first cata-
logue of Indian earthquakes. Richard (right) made definitive studies of individual earthquakes (1819, 1869, 1881
and 1897) in addition to identifying for the first time p-waves and s-waves, and the core of the earth.

ically printed and circulated to each administra-
tive outpost. An earthquake in India was some-
thing of a rarity and generated detailed letters
from residents describing its effects. Very often
the same report would be copied verbatim from
one newspaper and reported by another. Few of
the original letters have survived, but the earth-
quakes in Kumaon in 1803, Nepal in 1833 and
Afghanistan in 1842 were felt sufficiently
widely to lead scientifically inclined officials to
take a special interest in the physics and geog-
raphy of earthquakes. Mallett’s (1853-1855)
global catalogues of earthquakes included sev-
eral from India, with a special section devoted
to the 1833 earthquake for which he discussed
seismic propagation velocities.

At about the time of the sequential publica-
tion of Mallet’s global catalogue an army officer
named Baird-Smith wrote a sequence of articles
(1843a,b,1844) in the Asiatic Society of Bengal
summarizing data from several Indian earth-
quakes and venturing to offer explanations for
their occurrence. He was writing shortly after the
first Afghan war which had coincided with a ma-
jor 1842 earthquake in the Kunar Valley of NE
Afghanistan (Ambraseys and Bilham, 2003b),
which must have impressed him and others in the

military service who were in NW India at the
time. Baird-Smith’s accounts of other earth-
quakes include citations from his sources.

The director of the Geological Survey of In-
dia, Thomas Oldham (1816-1878) published
the first real catalog of significant Indian events
in 1883. His catalog includes earthquakes from
893 to 1869, and acknowledges the works of
Mallet and Baird-Smith. His important addi-
tions include verbatim textual extracts with ref-
erences that permit verification and further
work. His notes on some of the earthquakes
form the first detailed studies of individual
earthquakes in India.

His son, Richard. D. Oldham (1858-1936),
wrote accounts of four major Indian earthquakes
(1819, 1869, 1881 and 1897). He completed first
his father’s manuscript on the 1869 Silchar,
Cachar, Assam earthquake which was published
under his father’s name (Oldham, 1884). He next
investigated the Mw = 7.9 December 1881 earth-
quake in the Andaman Islands, visiting and map-
ping the geology of some of the islands (Old-
ham, 1884, 1885). He mistakenly located the
event deep in the northern Bay of Bengal based
largely on timing data from clocks in Calcutta
and Madras. An analysis of the tsunami generat-



quake on the northern edge of the Rann of
Kachchh close to what is now the India/Pak-
istan border. The earthquake figures prominant-
ly in Lyell’s Principles of Geology (1830) as
one of the first clear examples of geological up-
lift associated with an earthquake.

Oldham’s 1928 account refers to, but does
not reproduce, Baker’s map and profile from a
leveling survey crossing the Allah Bund. This
profile is key to quantifying the mechanism of
the earthquake, and it is entirely due to its
serendipitous discovery by Oldham (1898) that
we have access to it. The map had been acci-
dently omitted in Baker’s original 1846 publi-
cation by the editor. In a frontispiece to the Ge-
ographical Society of Bombay in 1846 he
apologizes for omitting the map and cross-sec-
tion and promises to include the figure in sub-
sequent issues, a promise that he failed to ful-
fill. Oldham had discovered the map quite by
accident when supervising a clean-up of the
Bombay office of the Survey of India. In his
discussion of the cause of the 1819 Allah Bund
earthquake Oldham speculates that the mor-
phology across the natural dam measured by
Baker in 1846 was caused by subsurface fault-
ing akin to that reported from Japanese earth-
quakes in the early 20th century.

Assuming the surface morphology to be
representative of co-seismic deformation dur-
ing a single earthquake, Baker’s 6 m crest-to-
trough observation is consistent with 11 m of
slip on a north-dipping reverse fault terminating
0.5-2 km below the surface (Bilham, 1999).
However, recent geological studies in the re-
gion (Rajendran and Rajendran, 2001 and
2002) have raised the possibility that the ob-
served morphology was a factor of two smaller
than that reported by Baker, and that its current
elevation of < 3 m crest-to-base is caused part-
ly by the 1819 event and partly by pre-1819
earthquakes. A difficulty in rejecting Baker’s
survey, a canal engineer of repute, is that he
would have made vertical errors of less than a
few cm in measuring topography over the 10
km width of the Allah Bund. Thus an error of 2-
3 m can be rejected. The cross-section that was
intended to accompany Baker’s account was
drafted from a larger scale survey deposited
with the Sind government. The smaller version

846

Roger Bilham

ed by this earthquake places it on the subduction
zone west of Car Nicobar (Ortiz and Bilham,
2003). His account of the 1897 Mw = 8.1 Shil-
long Plateau earthquake in Assam (Oldham,
1899) was exemplary, and according to Richter
provided the best available scientific analyses of
available physical data on any earthquake at the
time. In contrast to the care with which he in-
vestigated the geological, geodetic and geophys-
ical aspects of the earthquake, Oldham’s reports
are thin on specific accounts of building damage
which he felt were often exaggerated. Despite
the care with which he interpreted the intensity
data available to him, his estimated intensities
for the 1897 earthquake on a modified version of
the Rossi-Forel scale are 1.5 to 3 intensity units
too high in the epicentral region (Ambraseys and
Bilham, 2003c).

R.D. Oldham’s accounts established a tem-
plate for the study of earthquakes that occurred
in India subsequently. The great earthquakes of
1905 Kangra (Middlemiss, 1910) and 1934 Bi-
har/Nepal (Dunn et al., 1939) were each as-
signed to Geological Survey of India special
volumes, but these never quite matched the in-
sightful observations of Oldham’s 1899 volume.
Investigations of the yet larger Assam earth-
quake of 1950 were published as a compilation
undertaken by separate investigators (e.g., Pod-
dar, 1953; Ray, 1953; Tandon, 1953). In many
ways this proved to be the least conclusive of the
studies of the 5 largest Indian earthquakes 1819-
1950. Information available to Indian authors on
the effects of the earthquake were confined
largely to a narrow corridor of information
along the Brahmaputra valley since access to Ti-
bet, Burma, or the tribal regions south of the epi-
center was unavailable. Regrettably geologists
did not make a thorough search for surface fault-
ing in the epicentral region and geodesy near the
epicenter was virtually non-existent.

4. Uncertainties associated with the 6 June
1819 Allah Bund earthquake

Oldham wrote his account of the 1819
earthquake in Kachchh in retirement in England
(Oldham, 1928). His monograph synthesized
all the data available for the Allah Bund earth-



847

Earthquakes in India and the Himalaya: tectonics, geodesy and history

of frontal fill and co-seismic slip could be tested
with suitable excavations, or seismic profiles, of
the northern edge of the bed of Lake Sindri.

While excavations of Sindri sedimentation
might clarify the discrepancy between historic
leveling and current morphology, the observa-
tion by Rajendran and Rajendran that two or
more earthquakes caused incremental changes
in the height of the Allah Bund requires down-
ward revision of the 11 m estimate of coseismic
slip to a more modest 5 m. Any further reduction
in the coseismic uplift of the Allah Bund can be
rejected based on Baker’s mapping of the eleva-
tion of the bed of the Narra River since this
would have been at river base-level before the
earthquake, unaffected by previous earthquakes.

The recent 26 January 2001 Bhuj earthquake
was associated with 3-6 m of slip (Bendick et
al., 2001). Since this occurred on a 40 × 40 km
rupture, and resulted in isoseismal intensity dis-
tributions throughout India similar to the 1819
earthquake (Hough et al., 2002), it is tempting to
assume that the two events had similar stress
drops and local attenuation relationships, and
somewhat similar geometry and magnitude. This
would require the along-strike length of the Al-
lah Bund earthquake to be shortened consider-
ably below the > 100 km length first suggested
by Oldham and adopted by all later authors. In
contrast, Ambraseys and Douglas (2004) favor a
Mw = 8.19 magnitude for this event, requiring
rupture dimensions consistent with those in-
ferred by Oldham (1928). 

5. Himalayan earthquakes 1 September
1803 and 26 August 1833

These earthquakes occurred at the western
and eastern ends of the inferred 6 June 1505
earthquake. The first of these events occurred
during the opening battles of the 2nd war against
the Mahrattas. In late August 1803 a British
Army had laid seige to the fort and town of Ali-
garh on the banks of the Calini River (between
the Ganges and Jumna) some 200 km from the
Himalaya. The commander of the British Army,
Lt. General Lake, writing to Wellesley on 1 Sep-
tember indicates that the strength of the defences
will require a one month seige. Yet, not three

published by Oldham included a typographical
error in the vertical scale, but it is unlikely that
gross drafting errors would have been intro-
duced. Moreover, the accompanying map view
of the river system is exact in many details
compared to recent satellite photos suggesting
that its execution was fastidious.

Several explanations can be invoked to rec-
oncile the leveling data and current morpholo-
gy. The first is that the uplift and subsidence
morphology may have changed since the
earthquake. For example, it is possible that
Baker’s measurements started at a lower verti-
cal datum than that available to the Rajendrans
in 2000. According to Burnes (1833) the foot-
wall subsided by 1-3 m, with maximum subsi-
dence near the scarp. Burnes’s two handwrit-
ten accounts in the Geological Society of Lon-
don describe slightly different views of the
river cut through the Allah Bund in 1827 and
1828 that suggest it was evolving in response
to the flood of 1826. Currently the sediments
of Lake Sindri slope upwards towards the
southern edge of the Allah Bund. In the past
180 years sediments eroded from the front of
the scarp, supplemented by sediments from
the Narra River in flood, would have filled any
depression fronting the scarp along the north-
ern shore of Lake Sindri resulting in a datum
possibly 2 m higher than that available to Bak-
er. The Rajendrans were unable to map verti-
cal profiles northward into the Sindh province
of Pakistan hence it may not have been possi-
ble to recover Baker’s northern datum.

A second possibility is to assume that the
southern edge of the Allah Bund has now been
eroded 1 km or more northward by monsoon
winds and floods driving waves across the 30-
50 km wide fetch of open water to its South. In
1827 the crest of the scarp was fewer than 600
m from its southern edge. Ablation of the crest
of the Allah Bund may have also occurred al-
though this is considered unlikely because Ra-
jendran and Rajendran report the survival of
surface geodetic monuments installed in 1860.

The subsidence deformation profile, now
buried beneath Lake Sindri, may in fact be better
preserved than the uplift profile, and this, at
some future date, may provide additional con-
straints of slip in the 1819 earthquake. The depth



848

Roger Bilham

days later Lake writes again to Wellesley that
they have successfully stormed the town with
minor loss of life. In contrast to Lake’s silence on
the earthquake that occurred between the two let-
ters, a member (Thorn, 1818) of the besieging
army describes violent shaking for 2 minutes at
midnight accompanied by collapse several build-
ings. The earthquake appears in part responsible
for the successful capture of the fort, either from
damage to its walls or distress to inhabitants, al-
though specific details are lacking.

A summary of materials available for the
1803 event is recorded by Ambraseys and Jack-
son (2003) who assign it an approximate mag-
nitude of Mw = 7.5. This was later revised to
Mw = 8.09 by Ambraseys and Douglas (2004)
using additional materials, who place it at the
weatern end of the 1505 rupture. The 1833
erathquake almost exactly 30 years later oc-
curred at the eastern end of the 1505 rupture. In
contrast to the extensive damage reported from
Tibet in 1505, few accounts of damage have
surfaced from Tibetan sources for these two
earthquakes, suggesting that they were signifi-
cantly less severe than the 1505 event. The one
exception to the apparent silence from Tibet for
the 1833 earthquake are accounts of damage
from members of the Nepal quinquennial trib-
ute delegation returning from Beijing who
brought with them accounts of the increasing
damage they encountered as they approached
the northern Nepal border (Bilham, 1995).

The Ms ≥ 7.7 August 1833 earthquake near
Kathmandu consisted of three shocks (Bilham,
1995). The first caused alarm and the second, 5
hours later, brought most people from their
homes. The mainshock (Mw = 7.69, Ambraseys
and Douglas, 2004) occurred 15 minutes later
causing widespread structural damage in India
and Nepal, but the combined loss of life in India
and Nepal was only 500 because most people
were already in the open, alarmed by the two
foreshocks. Newspaper reports of these events
are abundant as are scientific commentaries in
journals in India and Europe. The isoseismals
from this earthquake suggest an epicentral re-
gion similar to, or at the western end of, the
1934 Ms = 8.1 rupture, which together with the
multiple shocks in the event, raises a number of
interpretational difficulties. The earthquake did

not affect western Nepal and its magnitude is
too small to have had much effect on releasing
strain accumulated since the 1505 earthquake.
However, had it occurred on the plate boundary
«detachment fault» it could not have released
much of the slip available to drive the larger
magnitude 1934 earthquake a century later.
Since the 1934 earthquake is believed to have
released up to 8 m of slip, and since potential
plate-boundary slip is renewed at a rate of less
than 2 m per century, the 1833 rupture would
have had to occur on different fault systems or to
have slipped on a small patch contiguous to the
1934 rupture. One possibility is that one or more
of the three 1833 earthquakes occurred deep in
the Indian plate where both strike-slip and thrust
faulting can occur, or that all three earthquakes
were M ≥ 7.5 thrust earthquakes at the Northern
edge of the 1934 rupture zone, similar to those
that have occurred in the past several decades in
western Nepal.

6. Cachar 10 January 1869

This M > 7 earthquake occurred in the Syl-
het region (Silchar) of what is now NE
Bangladesh. Although numerous accounts of
this earthquake were compiled by the Old-
hams the data are insufficient to estimate a
causal fault or a precise magnitude. Am-
braseys and Douglas (2004) estimate
Mw = 7.39. The most likely fault to be associ-
ated with this earthquake is the eastern ex-
tremity of the Dauki fault, as hinted by God-
win-Austin (1869) who was undertaking first-
order triangulation in the region at the time.
Few first hand accounts of the event exist out-
side the covers of Oldham (1884) but the oc-
casional letter describing its effects surfaces.
An example is reproduced below:
«The earthquake has not been a single shock
but has lasted, on and off, a month - nay it is
said some of the shocks have gone on rocking
for five minutes by the watch till some people
were literally sea sick. The bazaar at Silchar
(the capital of Cachar) is the handsomest street
anywhere east of Calcutta and it has been en-
gulfed. i.e. it has gone bodily down not at once
but in a series of descents, some ten feet at a



849

Earthquakes in India and the Himalaya: tectonics, geodesy and history

time. The river in Silchar in the cold weather
runs about 50 feet below the level of its banks
which are only dried mud, and the country has
been so rocked up and down till the river has cut
its banks right down to its own level and the
plain at Silchar is all one debris with no partic-
ular river anywhere. The commissioner told me
on Monday last that it was officially reported
that the only thing left standing at Silchar was
Clarke’s bridge, and it was the most wonderful
sight that ever was seen.» (Clarke, 1869)

The dangers of speculating on a causal fault
or mechanism for the 1869 earthquake are high-
lighted by radical errors of a century of inter-
pretations of the 1897 earthquake that were
shown to be baseless once the geodetic signal
was assessed in 2001. It is possible that enough
of the 1869 geodetic survey network was in
place prior to the earthquake to render its re-
measurement even now of value.

7. The 31 December 1881 Mw == 7.9 
Car Nicobar earthquake

This earthquake caused minor damage in
the Andaman Island Penal colony and generat-
ed a tsunami that was observed throughout the
Bay of Bengal but not along the Burmese
coast. The tsunami did no damage around the
Bay of Bengal where tide gauges recorded a
maximum amplitude of 0.8 m (Oldham, 1884).
An analysis of five tide gauge records reveals
that the earthquake was Mw = 7.9 ± 0.2 and oc-
curred on an east-dipping thrust fault below
and to the west of Car Nicobar, an island at
9°N midway between the Andaman and Nico-
bar islands (Ortiz and Bilham, 2003). GPS
measurements at Port Blair indicate oblique
convergence of the plate boundary (Paul et al.,
2001). The earthquake is believed to have oc-
curred on the interface between the Indian and
Andaman Plates and the inferred mechanism of
westward slip of the hanging wall slip is con-
sistent with slip partitioning between the dip-
ping subduction zone, and the strike-slip west
Andaman fault east of Car Nicobar.

A feature of this earthquake is the inferred
presence of a region of minor slip NE of the
main rupture zone. This may have been a sec-

ondary earthquake triggered by the mainshock.
Its timing would have to have occurred within a
few minutes of the mainshock for it to have pro-
duced the sea wave observed at Port Blair. Local
populations were concentrated in only two is-
lands and therefore there is no corroboration of
this inferred northern region of submarine fault-
ing which occurred between them. It is probable
that offshore corals may be of use in recon-
structing an extended history of earthquakes in
the Andaman-Nicobar Islands. The island of Car
Nicobar is believed to have been raised and tilt-
ed during the 1881 event. Deformation models
that do not include this uplift result in an inap-
propriate estimate of the observed tsunami run-
up on the island (Ortiz and Bilham, 2003).

8. 1897 Shillong Plateau Earthquake

The 1897 Great Assam earthquake (Ms = 8.0)
for more than a century was believed to have oc-
curred on a thrust fault dipping gently to the
north. Some considered it to have been a Hi-
malayan basal thrust. We now recognize that the
earthquake occurred on a reverse fault dipping
steeply to the south. Slip during the 1897 earth-
quake may have exceeded 16 m, resulting in 10
m uplift of the northern edge of the plateau.

Oldham clearly recognized the value of sur-
face deformation as a quantitative measure of
what happens in an earthquake, but the analyti-
cal tools to interpret these data were not to
emerge for a further half century. In 1897 cor-
respondence with the Surveyor general, Sydney
Burrard, Oldham requested a geodetic re-survey
of the Shillong Plateau. The work undertaken
by J. Bond covered only the southern half of the
plateau and was considered by Burrard (1898)
to be inferior in accuracy to normal survey stan-
dards because numerous triangles did not close
precisely. (A test of survey accuracy is whether
angles in a triangle after correcting for spherical
excess add up to 180°). We now know that these
misclosures were probably due to postseismic
adjustments in the epicentral region continuing
after the earthquake. The 1897 displacement re-
sults available to Oldham were ambiguous: ei-
ther the plateau had bodily expanded and risen
with no southward motion, or it had risen with-



850

Roger Bilham

out strain and moved southwards by slip on the
Dauki fault bordering its southern edge. Realiz-
ing this, Oldham urged resurvey of the northern
half of the plateau but he was destined never to
see the data since it was completed in 1936, the
year he died (Davison, 1936). Analyses of angle
changes between 1869 and 1936 reveal that
Oldham’s instincts were correct. The fault that
slipped in 1897 was a 110-km-long blind re-
verse fault beneath the northern edge of the
plateau, dipping southward at 45° with 16 ± 5
m of slip between 9 and 39 km (Bilham and
England, 2001). We named this unmapped fault
the Oldham Fault in his honour.

The earthquake raised the northern edge of
the plateau roughly 10 m. The causal fault is be-
lieved to have cut right through the lower crust
but did not approach closer than 9 km to the
Earth’s surface. Oldham (1899) photographed
secondary faulting of up to 10 m at the western
end of the plateau on the Chedrang fault. The
1.6 km mean-height of the plateau surface ap-
pears to have been driven to its current position
by reverse faults acting on both its northern and
southern edges. Three dissected terraces border
the northern edge of the plateau that may be
separated by active faults, but none have been
mapped by geologists possibly due to the thick
forest cover that makes access difficult.

Enigmatic aspects of this earthquake concern
the uniqueness of the Shillong plateau which
permits contraction of the Indian plate within 80
km of the Himalaya convergence zone, thereby
reducing the productivity of Himalayan earth-
quakes. An uplift rate of 2.5 ± 1 mm/yr can be
calculated from the current elevation of the
plateau, and from the date of its initial elevation
estimated from changes in sedimentation styles
in northern Bangladesh. This convergence re-
quires a convergence rate of 4 ± 2 mm/yr, or ap-
proximately a factor 4 less than the India/Tibet
convergence rate (Bilham and England, 2001).
The only large historical earthquake known in
the Bhutan Himalaya is the 1713 event described
in Ambraseys and Jackson (2003) and the pre-
cise location of this event is far from certain.

The southern edge of the Shillong Plateau is
truncated by the Dhauki fault. In order that the
surface of the Plateau be horizontal the Dhauki
fault must also act as a reverse fault, and this

raises additional concerns. No historical earth-
quakes have been recorded on this fault, and
many previous studies interpret the fault as a
dextral strike-slip fault. Although the fault may
have slipped differently in the past there is little
doubt that reverse slip is now the prevailing
mechanism, and has been so for the past one or
two million years. Earthquakes beneath the
plateau have thrust mechanisms parallel to the
strike of the Oldham fault at depths of more
than 35 km. The 1869 Cachar earthquake de-
scribed by the Oldhams may have occurred at
the Eastern end of the Dhauki fault (Godwin-
Austin, 1869; Oldham, 1884).

A recent review of instrumental records of
the 1897 earthquake reveals its teleseismically
derived magnitude to be Ms = 8.0 (Ambraseys,
2000) effectively the same as its geodetic seis-
mic moment of M = 8.1 (Bilham and England,
2001). A re-evaluation of Oldham’s 1897 iso-
seismal intensity data supplemented by addi-
tional data from newspapers, diaries, books and
government reports unavailable to Oldham, re-
veal significantly reduced areas for contours of
I > VIII isoseismals, but similar areas for lower
intensity shaking. The newly evaluated intensi-
ties include data from Tibet and Bhutan (Am-
braseys and Bilham, 2003c).

9. Kangra 1905 M == 7.8 earthquake

Occurring just 7 years after the 1897 Assam
earthquake, the Kangra event found the geolo-
gists of India eager to map the details of the
event. The earthquake had its oddities – in par-
ticular a prominent epicentral region of Rossi-
Forel shaking of intensity VIII to X near Kangra
and Dharmsala and an island of VIII shaking al-
most 250 km to the SE near Dehra Dun. This,
and an artificially-inflated estimate for magni-
tude (Richter rounded Gutenberg’s calculated
magnitude upward from M = 7.8 to M = 8; see
Ambraseys and Bilham, 2000), led several in-
vestigators to assume that rupture may have ex-
tended more than 350 km along strike.

Although geodetic measurements existed
along the probable southern edge of the rupture,
no remeasurements were made after the earth-
quake except near the remote region of high ac-



851

Earthquakes in India and the Himalaya: tectonics, geodesy and history

celerations near Dehra Dun. No horizontal de-
formation was detected and a vertical deforma-
tion signal, though discussed by many subse-
quent investigators, has recently been dismissed
as an artifact of the leveling process (Bilham,
2001). Hence there is little evidence to believe
that its rupture exceeded 200 km. First-order tri-
angulation prior to the earthquake is limited to
the southern edge of the inferred rupture zone
and it appears not to have been re-measured
since its initial measurement in 1845. An inter-
pretation of a GPS occupation of some of these
points in 2001 is currently underway. Intensities
of this event are re-evaluated by Ambraseys and
Douglas (2004).

10. Discussion

The above review of early earthquakes and
case histories of some of the larger earthquakes,
omits numerous smaller ones felt by individuals
or communities. The larger ones form a patchy
history that may be complete for the past 200
years, but which is certainly missing many
large earthquakes before then. An important
question is whether there is scant information
on pre-muslim or medieval earthquakes be-
cause there were few events, or whether it is be-
cause we have no records of them. Although
this question cannot be answered from the his-
torical record alone we may consider extreme
scenarios as a guide to future searches to re-
solve the issue.

Aggravating our lack of knowledge of previ-
ous earthquake is the curious observation that
none of the numerous earthquakes that have oc-
curred in India and the Himalaya in the past sev-
eral centuries have produced surface ruptures,
with the exception of secondary surface faulting
in the 1897 earthquake (Oldham, 1898), and sur-
face fractures of the 1993 Latur earthquake (See-
ber et al., 1996). In 1505 and 1892 surface fault-
ing was observed at the surface along the Pak-
istan/Afghanistan border (Ambraseys and Bil-
ham, 2003a) but no surface faulting has ever
been reported in the Himalayan and Indo-Bur-
man plate boundaries, despite geological indica-
tions that surface rupture of the frontal faults has
occurred in the past (Wesnousky et al., 1999).

The primary ruptures of the largest mid-plate
events of the past two centuries, the 7.8 < M < 8.1
1819 Allah Bund, the M = 8.1 1897 Shillong, the
M = 7.3 1931 Mach, and the M = 7.6 2001 Bhuj
earthquakes have all been on blind thrust faults,
dipping at approximately 45°, terminating 1-9
km below the surface, and extending to the base
of the crust. Thus, although they have caused
widespread destruction in the historical record,
the geological manifestation of their passage is
limited to secondary cracks and liquefaction phe-
nomena that tell us little about their mechanisms.
Such knowledge about rupture geometries as we
have obtained for these earthquakes, with the ex-
ception of the most recent, has been derived al-
most entirely from sparse geodetic data.

The conclusion to be derived from this ab-
sence of surface ruptures in the subcontinent is
that many historical earthquakes occurred on
faults that are currently unmapped, and the
corollary is that there may exist many hun-
dreds of subsurface faults potentially awaiting
re-activation for which we have no geological
intelligence.

The mechanisms of the numerous smaller
shocks that appear in historical Indian cata-
logues must be inferred from modern focal
mechanisms in those same geographic settings.
The inherent problem in doing this is that focal
mechanisms in some parts of India, e.g., the Hi-
malayan foothills, vary with depth. Surviving
intensity data are rarely adequate to distinguish
between deep and shallow shocks.

10.1. Intensity and attenuation

Estimates of intensities for the two largest
earthquakes of the past two centuries (1905 and
1897) have revealed that previous estimates of
Rossi-Forel or Modified Mercalli intensity tend
to exaggerate high intensity shaking by 1-3 in-
tensity units (Ambraseys and Bilham, 2003c)
whereas lower intensities (V-II) are estimated
with reasonable accuracy. The reason for this
exaggeration is that the style of building con-
struction suffers significant damage at intensi-
ties around VII-VIII and that subsequent shak-
ing produces somewhat imperceptible addition-
al damage (Ambraseys and Bilham, 2003b).



852

Roger Bilham

Even quite recent intensity estimates can be
suspect. For example, the 1989 Udaypur earth-
quake in southern Nepal resulted in both Nepali
(Pandey and Nicolas, 1989; Dikshit and
Koirala, 1989) and Indian (Sinha, 1993) inten-
sity and engineering damage studies. The re-
sulting intensity contours show an abrupt jump
of 1-1.5 intensity units at the Nepal/India bor-
der where the two studies abut.

The re-evaluation of the felt intensity reports
for the 1833, 1897, 1905, 1934 and 1950 earth-
quakes on a common scale is an important pri-
ority, that has been partly completed by Am-
braseys and Jackson (2003), since it may reveal
the details of seismic hazards in intervening re-
gions where future Himalayan earthquakes are
anticipated. Currently more than three scales
have been used to report these data. Rossi-Forel,
Modified Mercalli and MSK intensities, with
caveats imposed by their specific inapplicability
to Indian building methods. In some areas ac-
celeration damage can only with difficulty be
distinguished from collapse caused by liquefac-
tion-induced foundation failure. In 1897 regions
of extensive liquefaction and catastrophic later-
al spreading follow the banks of the main rivers
and result in building damage from foundation
collapse, rather than grades of shaking intensity.
Ambraseys and Bilham (2003c) separated lique-
faction observations from MSK assignations
based on shaking intensity lest they bias the ar-
eas of isoseismal contours.

10.2. Himalayan recurrence interval

The recurrence interval for great Himalayan
earthquakes remains conjectural since the histor-
ical record is probably incomplete even for the
past 500 years. A summary of those events for
which we have data is depicted in fig. 4a,b, al-
though both the rupture area and the amount of
slip are unknown for each of these events. The
figure suggests that the western Himalaya may
have slipped in a sequence of events between
1501 and 1555, and that since then there have
been relatively modest earthquakes, insufficient
to release the 1.5-1.8 m per century of accumu-
lating convergence revealed from geodetic meas-
urements. The largest of the pre-1900 earth-

quakes, the 6 June 1505 Kumaon/western Nepal
earthquake (Jackson, 2002; Ambraseys and
Jackson, 2003), may have exceeded Mw = 8.2,
and its recurrence now would result in a similar-
sized earthquake (9 m of slip along a 500-600
km rupture zone). Damage in northern India was
considerable during the 1505 event and it is like-
ly that its recurrence would damage many of the
large cities along the Ganges and Jumna rivers
through shaking, and from the effects of exten-
sive liquefaction. Smaller seismic gaps are evi-
dent in Kashmir, in Sikkim and in Assam for
which the historical record is ambiguous or ab-
sent.

Assuming that seven to ten great ruptures
permit the slip of the entire Himalayan Arc, and
a recurrence interval of 500 years (≥ 9 m slip on
200-300 km long, 70-90 km wide, ruptures) we
should anticipate M ≥ 8 earthquakes occurring
every 50-70 years. Insufficient earthquakes
have occurred recently to match this estimate.
Two great earthquakes only that approach this
severity have occurred in the past 200 years
(1934 and 1950), and two others are known in
the previous 300 years (Kashmir, 1505, 1555).
No great earthquake has occurred for 53 years.
Almost two thirds of the Himalaya remain un-
broken by recent earthquakes, suggesting that
several seismic gaps may currently exist. Final-
ly, the summation of seismic moment from all
known earthquakes since 1505 along the entire
arc yields a slip rate less than 30% of that de-
rived from the current geodetic slip rate (Bil-
ham and Ambraseys, 2004).

From these arguments we may form one of
two conclusions: that one or more great Hi-
malayan earthquakes are overdue, or that our
understanding of the way in which the northern
plate boundary slips is flawed. The case for the
imminent failure of a seismic gap is hampered
by the absence of any well documented recur-
rence interval, or indeed any evidence for regu-
lar failure of the Himalayan plate boundary.
The absence of constraint permits the extreme
view, for example, that failure occurs in clus-
tered sequences, as may have occurred in the
western Himalaya 1400-1555. If indeed this se-
quence released accumulated displacements in
the western Himalaya five centuries ago, then a
case can be made for the immediate recurrence



853

Earthquakes in India and the Himalaya: tectonics, geodesy and history

Fig.  4a,b. a) The Himalaya describe a small circle that subtends an arc of approximately one radian symmet-
rically about the Thakola Graben in Tibet. Important mid-plate earthquakes named. Microseismicity follows this
small circle (from Engdhal et al., 1998) and is negligible to its south where great earthquakes are located. b) The
arcuate box is expanded (and straightened) and it shows time distance plot of approximate rupture areas of large
earthquakes in the past eight centuries plotted along the arc (approximate transverse-Mercator projection of lin-
ear transverse-km versus angular distance). One or more large earthquakes appear to be overdue in Kashmir, Ku-
maon and Western Nepal. We know of no earthquakes in Sikkim, and the 1897 Assam Shillong earthquake may
have reduced the slip potential in Eastern Bhutan. Pre-1500 earthquakes are known with less certainty. Trench
studies have revealed slip on the frontal thrusts at the beginning of the 15th century at several locations west of
Dehra Dun (Senthil Kumar, per. comm., 2004) and surface rupture on frontal thrusts in eastern Nepal may cor-
respond to the earthquake that destroyed Kathmandu in 1255 (Rockwell, pers. comm., 2004).

a

b



854

Roger Bilham

of one or more 9 m slip events, based on the
current convergence rate of 18 mm/yr. The re-
gion of the 1505 earthquake has been hitherto
termed the Central Himalayan seismic gap by
Khattri and Tyagi (1983) and Khattri (1987).

Alternatively, the assumption that great
earthquakes are essential features for plate
boundary slip may be incorrect – the Himalaya
may fail in smaller events that incompletely rup-
ture the plate boundary. These smaller events
might be considered to be similar to the ChiChi
earthquake of 1999 that ruptured through a mid-
level segment of the accretionary wedge, rather
than through a basal detachment. Such events
may accommodate convergence without trans-
lating the entire Himalaya southward over India.
The major 1833, 1885 and 1905 earthquakes
(7.5 < Mw < 7.8) may have been examples of
these «out-of-sequence thrusts». 

One of the most troubling observations, that
might be accounted for by out-of sequence
thrusting or deep events, is that no recent Hi-
malayan earthquake has ever resulted in a
recorded surface rupture. Such ruptures have
obviously occurred in recent geological time,
on the main frontal thrusts for example (Wes-
nousky et al., 1999), signifying either that re-
cent earthquakes are anomalously small, or that
the search for surface rupture may not have
been exhaustive. If some, but not all, great
earthquakes rupture the Himalayan frontal
thrusts we cannot hope to quantify the recur-
rence interval from these events using paleosis-
mic fault-trenching methods.

Out of sequence thrusts cannot represent a
steady-state condition for Himalayan slip since
it would not explain the geological observation
of occasional slip on the basal thrust systems
and Main Frontal Thrusts. However, it is possi-
ble that excessive recent erosion of the Hi-
malayan foothills may have upset the uniform
taper of the Himalayan accretionary wedge
such that adjustments are now underway that
result in a predominance of high-level thrusting
interspersed with infrequent basal thrusts.

Historical studies have an important role in
distinguishing between these various scenarios,
yet it is unlikely that we shall ever find a history
that is complete across- and along- the Himalaya,
even near the Kathmandu and Kashmir Valleys

that have been administered continuously by a
record-keeping population for the past thousand
years. For this reason, trench investigations of
faults and liquefaction features will be necessary
to fill in the record. In practice, the subsurface
record of strong-ground motion is complete, but
its interpretation may be non-unique, suitable
conditions may not exist everywhere for it to be
recorded, and it is insensitive to small earth-
quakes whose recurrence may be quite damaging.

10.3. Mid-plate recurrence intervals

Although numerous micro-earthquakes, and
many damaging shocks have occurred in the
past several centuries in India, the geodetic sta-
bility of the plate, and the absence of recent
mountain ranges indicates that earthquakes
should not recur repeatedly on the same fault
during the written history of India. Yet archeo-
logical observations in India suggest earth-
quakes may have repeatedly destroyed early
settlements there, especially in westernmost In-
dia. Rajendran et al. (1996) present evidence
for reactivation of the fault causal to the Latur
earthquake. The town of Latur itself, like many
Indian villages, is a mound city built on the ru-
ins of previous cities.

The occurrence of the M = 7.6 Bhuj 2001
earthquake less than two centuries after the
M ≥ 7.8 Allah Bund 1819 earthquake has been
considered by some investigators to represent a
short recurrence interval for earthquakes in
mid-plate India. Such an appraisal would be in-
correct because the two events did not, of
course, rupture the same fault, nor even the
same fault system. The two earthquakes oc-
curred on the ancient Kachchh rift zone, an
east-west fault system that can be traced struc-
turally from near Karachi to Ahmedabad. In a
study of the 1819 event it was concluded that
contiguous future faulting might be anticipated,
with specific concern that rupture to the west
would create hazards for Karachi (Bilham,
1999). As it happened, rupture in 2001 occurred
2-4 rupture lengths to the east of the 1819
earthquake. Hence there is a possibility that the
entire Kachchh rift may be converging. In fact
geodetic data suggest that the rift north of the



855

Earthquakes in India and the Himalaya: tectonics, geodesy and history

Bhuj region may have converged by more than
1 m since 1856 (Sri Devi et al., 2003). Should
this be the case, additional large earthquakes
may be anticipated both to the east and west of
the 1819 and 2001 earthquakes.

The observed geodetic convergence of the
Rann of Kachchh by 9 ± 3 mm/yr is approximate-
ly 2-3 times larger that the entire geodetic con-
vergence rate between Northern and Southern In-
dia (Paul et al., 2001). Two explanations for this
have been proposed: one is that a 400 km wide
continental «Sindh flake» is in the process of
fracturing from the NE edge of the Indian plate
(Stein et al., 2002), the other is that the intercon-
nected ancient rift systems of northern India de-
fine a small northern plate « the Harappan plate»
that allows a large triangle in NE India between
the central Himalaya and Bhuj to converge with
the main body of the Indian plate to the south
(Bilham et al., 2003). Support for either mecha-
nism of plate fragmentation is weak, and future
geodetic observations are needed to resolve the
extent of plate deformation in NE India.

11.  Conclusions

The tectonic setting of India’s collision with
Asia is now reasonably well characterized from
recent seismicity and geodetic studies of rela-
tive motion at their plate boundaries. Direct
measurements across and within the Himalaya
reveal a locking line beneath the edge of the Ti-
betan Plateau and the absence of creep to its
south (Bilham et al., 1995, 1998, 2001), imply-
ing that the advance of the Himalaya over the
Indian plate proceeds largely through the recur-
rence of great plate boundary earthquakes.

Earthquakes within the Indian plate are at-
tributable to the superposition of the NW com-
pressional stress of collision, on the stresses
arising from plate flexure. The depth and
mechanisms of recent earthquakes reflect the
sense of these combined stresses.

A several millennia-long written record in
India has revealed few major earthquakes pri-
or to the past two centuries. This is partly due
to the fact that extant records have yet to be
searched rigorously for earthquakes, but is in
part due to the corruption of potentially valu-

able records and their loss through fire, war
and decay. Despite their sparseness it is like-
ly that documents on historical earthquakes
will surface in Tibetan, Urdu and Arabic
records that will change current estimates of
the significance of seismic gaps in the Hi-
malaya, and may change our understanding
of earthquakes within the Indian continent.

Our current understanding of Himalayan
earthquakes is such that we may calculate po-
tential slip in several segments of the plate
boundary, but we cannot estimate the timing
of future events. Making assumptions about
the probable completeness of the historical
seismic record we can estimate estimate min-
imum slip potential based on the time since
the last known earthquake (Bilham et al.,
2001). This has moderate relevance to plan-
ning for future earthquakes. The eventual es-
tablishment of recurrence intervals for Hi-
malayan ruptures will require a combination
of serendipitous historical studies and geolog-
ical trench investigations of faulting and
earthquake-induced liquefaction features.

Acknowledgements

R.S. Cox of the American Philosophical
Society provided a copy of C.B. Clarke’s let-
ter concerning the Silchar earthquake. I
thank the organizers of the Erice conference
on historical earthquakes for inviting my par-
ticipation. I also thank an anonymous re-
viewer for amusing and insightful comments
on the first draft of this article. The study was
funded by the National Science Foundation
EAR-0003449.

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