articolo fenton.pdf


Key  words paleoseismicity – active faulting –
Thailand

1.  Introduction

Due to a lack of large, damaging earth-
quakes during historical time, Thailand has 
not been considered to be a seismically active
country. Although there are a number of ac-
counts of historical earthquake damage (Nuta-
laya et al., 1985), the locations and sizes of most
of these events are not well constrained. It is
likely that some historical earthquake damage
in Thailand may have been the result of large

earthquakes on distant faults such as the Sa-
gaing Fault in Myanmar and faults in Southern
China, which have been the locus of several
magnitude (unspecified scale) > 6.0 earthqua-
kes during historical time (Le Dain et al.,
1984). Recent seismicity in Thailand has been
confined to low to moderate levels with no clear
association with existing mapped faults (Bott et
al., 1997). In areas like Thailand, where there is
no reliable, long-term earthquake record and an
absence of historical fault surface ruptures, it is
necessary to examine the geologic and geomor-
phic record, in order to quantify the activity on
suspected active faults, and thereby determine
their contribution to the seismic hazards of the
region.

A fault is deemed active and is considered
to be a potential source of future earthquakes if
the fault: 1) displays geomorphic features in-
dicative of recent fault activity; 2) there is evi-

957

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

Mailing address: Dr. Clark H. Fenton, URS Corporation,
500 12th Street, Suite 200, Oakland, CA 94607, U.S.A.; e-mail:
Clark_Fenton@URSCorp.com

Recent paleoseismic investigations 
in Northern and Western Thailand

Clark H. Fenton (1), Punya Charusiri (2) and Spencer H. Wood (3)
(1) URS Corporation, Oakland, CA, U.S.A.

(2) Department of Geology, Chulalongkorn University, Bangkok, Thailand
(3) Department of Geosciences, Boise State University, Boise, ID, U.S.A.

Abstract
Recent paleoseismic investigations have identified a number of active faults in Northern and Western Thailand.
Northern Thailand is an intraplate basin and range province, comprised of north-south-trending Cenozoic inter-
montane grabens and half grabens, bounded by north- to northwest-striking normal to normal-oblique faults and
northeast-striking left-lateral strike-slip faults. The basin-bounding normal faults are marked by steep, linear
range fronts with triangular facets and wineglass canyons and have slip rates of 0.1 to 0.8 mm/yr. Based on limi-
ted data, the average vertical displacement-per-event is about 1.0 to 1.5 m. These faults are characterized by
recurrence intervals of thousands to tens of thousands of years and are capable of generating earthquakes up to
moment magnitude (M) 7, and larger. The northeast-striking strike-slip faults are marked by shutter ridges, and
deflected drainages. Slip rates are 3 mm/yr or less. Western Thailand is dissected by a number of northwest- and
north-northwest-striking, right-lateral strike-slip faults related to the Sagaing Fault in Myanmar. Although show-
ing much less activity than the faults in neighboring Myanmar, these faults display abundant evidence for late
Quaternary movement, including shutter ridges, sag ponds, and laterally offset streams. The slip rate on these
faults is estimated to be 0.5 to 2.0 mm/yr. These faults are considered capable of generating maximum earth-
quakes of up to M 71/2.



dence for displacement in young (Late Qua-
ternary) deposits or surfaces; and/or 3) is asso-
ciated with a moderate- to large-magnitude his-
torical earthquakes or a pattern of micro-
earthquakes suggestive of an active fault. 

In this paper, we summarize the results of
several recent investigations of active faults in
Northern and Western Thailand. The evidence
for active faulting, illustrated by examples from
the Thoen, Pua, Mae Chan, and Three Pagodas
faults, and the characteristics of these faults are
discussed.

2.  Tectonic setting

The contemporary tectonic framework of
Southeast Asia is a consequence of the inter-
action between the Indo-Australian and Eura-
sian plates (fig. 1), and the more distant Philip-
pine and West Pacific plates. The Eurasian
plate, within which Thailand is situated, is
surrounded by convergent margins, including
the Andaman thrust and Sunda arc, to the west
and south, respectively. Australia is moving
northward (along a vector of 010° to 020°),
towards Southeast Asia, with a convergence
rate of 65 to 70 mm/yr (McCaffrey, 1996). In
addition, Southeast Asia may also be moving
towards Eurasia at a rate of 10 mm/yr. De-
formation across these plate margins is dif-
fuse. Partitioning of oblique convergence along
the Andaman and Sumatra-Java margins gives
rise to broad, complex zones of deformation (fig.
1) involving both subduction and transform fault-
ing (Malod and Kemal, 1996), the most notable
of the latter being the Sumatra Fault. Persistent
deformation within the Eurasian plate is illustrat-
ed by the number of seismogenic faults in this
region (Molnar and Deng, 1984).

Thailand occupies an intraplate setting
within the Eurasian plate. The present tectonic
stress regime in Thailand is one of transten-
sion, with opening along north-south oriented
basins and right-lateral and left-lateral slip on
northwest- and northeast-striking faults, respe-
ctively (Polachan et al., 1991; Packham, 1993).
This regime of transtensional faulting was initiat-
ed sometime between the Late Cretaceous and
Early Tertiary (Polachan et al., 1991; McCabe et

958

Clark H. Fenton, Punya Charusiri and Spencer H. Wood

Fig.  1.  Major tectonic elements in Southeast Asia
and Southern China. Arrows show relative directions
of motion of crustal blocks during the Late Cenozoic.
MPFZ - Mae Ping Fault Zone; NTFZ - Northern
Thailand Fault Zone; TPFZ - Three Pagodas Fault
Zone; UFZ - Uttaradit Fault Zone. Modified from
Polachan et al. (1991).

al., 1988). The Cenozoic tectonics of Thailand,
and Southeast Asia as a whole, are a conse-
quence of collision of India with Eurasia.
Collision began about 50 Ma (Middle Eocene)
and has resulted in 2000 to 3000 km of short-
ening across the Himalayan orogen (Peltzer
and Tapponnier, 1988). As India drove into the
southern margin of Eurasia, Indochina was
rotated clockwise about 25° and extruded to the
southeast by approximately 800 km along the
Red River and Wang Chao-Three Pagodas



fault zones during the first 20-30 million years
of collision (Peltzer and Tapponnier, 1988).
Extrusion migrated northwards onto the Altyn
Tagh Fault as collision progressed. Rotation of
Indochina continued, reversing the sense of
motion of the Red River Fault from left-lateral
to right-lateral (Allen et al., 1984; Peltzer and
Tapponnier, 1988). Differential slip between
the main strike-slip faults, from north to south,
the Red River, Mae Ping, Three Pagodas, and
Sumatra fault zones (fig. 1), created a transten-
sional regime that resulted in the opening of the
Tertiary basins in Southeast Asia (Ducrocq et
al., 1992).

The Tertiary basins of Thailand are grabens
or half grabens, typically bounded by north 
to northwest-striking normal faults (Polachan 
et al., 1991; Lorenzetti et al., 1994). The loca-
tion and geometry of the basins are controlled by
the north-south structural grain in pre-Triassic
rocks and pre-existing northwest-striking, strike-
slip faults (O’Leary and Hill, 1989). Basin evo-
lution throughout Thailand follows a roughly
similar sequence of events. The main phase of
strike-slip tectonism, resulting in rapid exten-
sion, with widespread fluvial sedimentation
(Oligocene-Early Miocene), was followed by
lacustrine sedimentation as basins became
increasingly isolated (Early-Middle Miocene).
Lacustrine sedimentation ended, and there was
an influx of coarse terrigenous clastics suggest-
ing a period of rapid, localized uplift (Middle-
Late Miocene). Finally, following a brief period
of basin inversion that resulted in a widely 
recognized Late Miocene unconformity, fluvial
sedimentation, generally coarsening upward, re-
sumed (Late Miocene-Recent) (Polachan 
et al., 1991; Remus et al., 1993; Alderson et al.,
1994). The climax of extensional tectonism is
marked by the eruption of Late Tertiary and
Early to Middle Quaternary alkaline basalts
(Hoke and Campbell, 1995). Paleomagnetic
data, showing localized rotations during the
Tertiary, indicates that the opening of these ba-
sins appears to have been fairly complex
(McCabe et al., 1988, 1993; Richter et al., 1993).

With the exception of the lignite-bearing
Mae Moh basin (e.g., Ratanasthien, 1986), few
non-proprietary studies have been carried out
to determine the detailed tectonic development

of these basins. The total amount of extension
across the region is unknown; Olinstad et al.
(1989) estimate about 50 km of Cenozoic
extension at the northern end of the Gulf of
Thailand. In addition, the thickness of basin-
fill sediments is poorly constrained and the
geometry of the basin-bounding faults are not
well known. Many of the basins, however, are
bounded by linear escarpments that display a
number of geomorphic features suggesting that
they may still be active structures (Siribhakdi,
1986).

3.  Seismotectonic provinces

We have modified the seismotectonic zones
of Nutalaya et al. (1985), incorporating geolog-
ic, heat flow, and fault activity data, to better
represent the seismotectonic character of
Thailand (fig. 2). Most of Northern Thailand
falls within what, on account of its tectonic sim-
ilarities with the Basin and Range Province of
the Western United States, Fenton et al. (1997)
have called the Northern Basin and Range
Province. This is a region of extended crust,
forming basin and range topography (Mac-
Donald et al., 1993). Heat flow is presently
moderate to locally high and probably has been
since the initiation of rifting in the early
Tertiary (Raksaskulwong and Thienprasert,
1991). To the west the Northern Basin and
Range is bounded by the Western Highlands, a
region of lower heat flow, comprising uplifted
and complexly folded and faulted metamorphic
rocks. This province is traversed by a number of
northwest- to north-northwest-striking right-
lateral strike-slip faults, including the Three
Pagodas and Mae Ping faults, which splay from
the Sagaing Fault in Eastern Myanmar (fig. 1).
To the east of the Northern Basin and Range 
is the Loei or Eastern Fold Belt, a transitional
zone between the extended crust of the Northern
Basin and Range and the Korat Plateau, an uplift-
ed plateau region with subdued topography, low
heat flow, and apparent tectonic quiescence. To
the south the Northern Basin and Range transi-
tions into the Central Plain (also known as the
Chao Praya Basin) which in turn transitions into
the Gulf of Thailand. Each of these provinces is a

959

Recent paleoseismic investigations in Northern and Western Thailand



region of extended crust, distinguished by an
increasing amount of extension and subsidence
towards the south. Whereas the Northern Basin
and Range comprises a number of distinct basins,
separated by intervening ranges, the Central Plain
has extended to the point where it has created a
single, broad, alluvium-filled topographic basin.
North of the Northern Basin and Range is a
region dominated by left-lateral strike-slip defor-
mation. This is called the Mae Chan Province
after the active strike-slip fault that appears to
mark the southern boundary of this deformation.

4.  Historical seismicity

Contemporary seismicity in the Northern
Basin and Range province is diffusely distrib-
uted, of low to moderate levels, does not appear
to be associated with currently mapped faults
(fig. 3), and is probably confined to the upper
10 to 20 km of the crust (Bott et al., 1997).
Although the historical earthquake record
extends back to at least 1300 A.D. (year 1843
B.E., Thai calendar), the largest known earth-
quake in Thailand has probably not exceeded
Richter magnitude (ML) 61/2. Associating seis-
micity with specific geologic structures, partic-
ularly mapped faults, is extremely difficult in
Northern Thailand because of the large location
uncertainties of individual earthquakes (Bott 
et al., 1997). In fact, in common with the Basin
and Range Province in the Western United
States, much of the widely distributed seismic-
ity in Northern Thailand is probably associated
with faults that have no clear surface expres-
sion (Bott et al., 1997). In the Basin and Range
Province, these so-called background earth-
quakes can be as large as M 6 to 61/2 (dePolo,
1994).

5.  Previous fault studies

With the exception of limited ground crack-
ing accompanying the 1983 ML 5.9 reservoir-
induced earthquake at Srinagarind reservoir
(Klaipongpan et al., 1991), there are no reports
of historical surface faulting events in Thailand.
Nutalaya (1994) and Hinthong (1995, 1997) ini-
tially compiled data on active faults in Thailand,
identifying 22 active, potentially active, or sus-
pected active faults, based primarily on geomor-
phic expression and thermoluminescence ages
obtained from fault gouges. Subsequent inves-
tigations have added to the inventory of active
and suspected active faults in Thailand (fig. 4).
Thiramongkol (1986) presented evidence for
Holocene movement on the Bang Pakong Fault
on the eastern margin of the Central Plain. Le
Dain et al. (1984) suggested that the northwest-
striking Papun (Moei or Mae Ping) Fault might
also be active, based on recent seismicity re-
corded in the Myanmar-Thailand border region

960

Clark H. Fenton, Punya Charusiri and Spencer H. Wood

Fig.  2.  Seismotectonic provinces in Thailand (after
Woodward-Clyde Federal Services, 1996).



961

Recent paleoseismic investigations in Northern and Western Thailand

Fig.  3.  Late Cenozoic faults and historical seismicity (1362 to 1996) of the Northern Basin and Range seis-
motectonic province. Figure modified from Bott et al. (1997).



(fig. 1). Earthquake focal mechanisms suggest
that this fault is a right-lateral, strike-slip fault
(Le Dain et al., 1984). Woodward-Clyde Feder-
al Services (1996) carried out extensive fault

investigations in Northern Thailand that showed
recent activity on the Mae Chan, Pua, Phrae,
Phrae Basin, Thoen, Nam Pat, Long, and
Phayao faults (fig. 3). Rhodes et al. (1996)
reported young faulting within Cenozoic sedi-
ments along the margin of the Chiang Mai
basin, west of the city of Chiang Mai. Perez 
et al. (1999) inferred recent movement on the
Mae Kuang Fault, northeast of Chiang Mai,
from the offset of three tributaries of the Mae
Kuang River. Wood (1995, 2001) provided
strong geomorphic evidence for Late Quater-
nary left-lateral displacement along the Mae
Chan Fault. Recent trenching investigations
have confirmed Late Quaternary faulting on the
Mae Chan Fault (Rymer et al., 1997). Wood-
ward-Clyde Federal Services (1998) highlighted
evidence for recent movement on the Three
Pagodas Fault in Western Thailand and also on
the Tavoy, Tenasserin, and Kungyaungale faults
in neighboring peninsular Myanmar. 

6.  Approach of recent investigations

The identification of active faults in Thai-
land has been hampered by: 1) the comparative
lack of fault studies; 2) extensive weathering of
bedrock and extremely active erosion acting
together to prevent the preservation of all but
the most resistant geomorphic features; 3)
large areas of thick forest vegetation, and 
4) the probable low slip rates of the intraplate
faults in Thailand. Combined, these factors re-
sult in a lack of recognizable, long-lived surface-
faulting geomorphic features (Fenton et al., 1999).
Despite these shortcomings, paleoseismic inves-
tigations in Thailand have been successful and
indicate that Late Quaternary deformation is
ongoing and that these active faults pose a signi-
ficant seismic hazard (e.g., Wong et al., 1997).

Lacking a well-defined Late Quaternary
framework for Northern Thailand, recent stud-
ies (e.g., Fenton et al., 1997) concentrated on
the geomorphic expression of faulting, and the
comparison with the features observed along
other active faults in similar tectonic settings
worldwide. These features included fault scarps,
faceted spurs, and offset terraces and drainages.
These geomorphic data were supplemented by

962

Clark H. Fenton, Punya Charusiri and Spencer H. Wood

Fig.  4.  Active and suspected active faults in Thailand.
Modified from Hinthong (1995).



paleoseismic data obtained from limited trench-
ing and fault zone exposures (Woodward-Clyde
Federal Services, 1996; Fenton et al., 1999).

Ideally, investigations of active faults prog-
ress from a regional, through a local, to a site-
specific scale. In areas where there is some data
on the regional neotectonic setting, the empha-
sis of such studies is on the local and site-spe-
cific scale. In Thailand, where damaging earth-
quakes are infrequent and possibly there are no
surface-faulting events in historical time, the
regional, as well as local seismotectonic setting
is not well understood. Therefore, investiga-
tions have to start at a regional level, and
progress through a series of logical steps
towards detailed site-specific studies.

Initial studies involved remote sensing in-
terpretation, starting at small scales with satel-
lite imagery, progressing to detailed stereoscop-
ic aerial photographs to locate zones of active
deformation (Wood, 1995, 2001; Fenton et al.,
1997). Once these zones were identified, de-
tailed mapping of Quaternary landforms and
deposits along a zone of deformation was car-
ried out. The Quaternary stratigraphic frame-
work was then established and landform styles
identified. Based on the estimated ages of these
features and/or deposits, they were used to meas-
ure the amount and the rates of displacement
across faults (Wood, 1995, 2001). Geomorphic
mapping aided in evaluating the location of
active faults and the nature of the faulting, iden-
tifying the number of paleo-events, and the
approximate size and timing of these events
(Fenton et al., 1999).

Finally, when there was sufficient know-
ledge of the local Quaternary stratigraphy and
geomorphology with which to evaluate the re-
sults of detailed trench logging, we excavated
and logged a number natural fault zone expo-
sures. A number of the faults investigated, even
after detailed geomorphic studies, were not
considered suitable for trenching studies be-
cause of the lack of preservation of young
deposits along the fault zones. These faults,
although having very prominent geomorphic
expressions, usually as topographic escarpments
with faceted spurs with oversteepened bases
(Hamblin, 1976), are rarely expressed in young
geologic materials.

These studies have allowed us to estimate a
number of fault parameters including: the total
amount of offset across fault zones; slip-per-
event; fault slip rates; recurrence intervals; fault
segmentation, and bracket the age of faulting
events. The geomorphic evidence for Late Qua-
ternary faulting in Thailand is discussed in the
following sections, illustrated by examples
from the Thoen, Pua, Mae Chan, and Three
Pagodas fault zones.

7.  Thoen Fault

The 120 km long Thoen Fault Zone (fig. 3)
is a series of north- to northeast-striking faults
that traverse the region between the Phrae Ba-
sin to the east and the Lampang, Mae Moh, and
Thoen basins to the west (Piyasin, 1974; Cha-
roenprawat et al., 1994). Two faults within this

Recent paleoseismic investigations in Northern and Western Thailand

Fig.  5.  Simplified map of the Thoen Fault System
showing fault segments and localities mentioned in
the text.

963



system display a number of structural, strati-
graphic, and geomorphic features indicating
recent movement. They are the fault bounding
the eastern margins of the Mae Moh, Lampang,
and Thoen basins, herein called the Thoen Fault,
and the fault bounding the western side of the
Long Valley, the Long Fault (fig. 5). 

On aerial photographs and Landsat TM sa-
tellite imagery, the Thoen Fault is a well-de-
fined, sharp lineament. The predominantly ver-
tical offset across the fault is highlighted by the
contrast between the deep incision by streams
in the uplifting footwall compared to the lack of
incision on the same streams in the subsiding
footwall, i.e. denudation and aggradation in the
footwall and hangingwall, respectively, of an
active fault. The Thoen Fault can be divided into
four segments, based on geomorphic expres-
sion, structural style, and sense of offset. From

north to south these are the Ban Mai, Doi Ton
Ngun, Mae Tan, and Thoen segments (fig. 5). 

Over much of its length, the Thoen Fault
forms a northwest-facing bedrock escarpment
that varies in height from 400 to 600 m. The
escarpment comprises a series of faceted spurs
interrupted by several benches or erosional ped-
iment remnants (fig. 6). Hamblin (1976) has
shown that such features were the result of epi-
sodic fault movement; the facets forming dur-
ing periods of fault movement and the benches
during periods of tectonic stability, erosion and
fault scarp retreat (fig. 7). Studies of faults in
the Mae Moh Basin, immediately to the west of
the Thoen Fault, have shown that extension
began sometime in the Early Oligocene (Vella,
1983; Ratanasthien, 1986). These faults show a
complex history of movement throughout the
Tertiary, however, they now appear to be rela-

Clark H. Fenton, Punya Charusiri and Spencer H. Wood

Fig.  6.  Triangular faceted spurs along the Thoen Fault escarpment east of Ban San Pa Pao. Note the oversteepened
base and the development of several erosional benches along the escarpment.

964



Progressive steepening towards the base of a
fault scarp or escarpment shows repeated fault
movement, the steeper bevels representing
more recent (less eroded fault scarps) faulting
episodes (McCalpin, 1996).

Several streams crossing the Ban Mai Seg-
ment exhibit wine-glass canyon profiles. This
results from renewed uplift or an increased rate
of uplift of the footwall in a normal fault sys-
tem (fig. 8). In order to equilibrate their profiles
across a fault-produced knickpoint, streams may
have to cut down rapidly when fault movement
either resumes after a period of tectonic quies-
cence or when the rate of movement increases.
The result of this rapid down-cutting is the for-
mation of a narrow slot canyon or stem of the
wine-glass. The presence of wineglass canyons
in addition to the marked steepening of the
faceted spurs at the base of the escarpment,
indicate that, at least along the Ban Mai Seg-
ment, the Thoen Fault is undergoing renewed or
increasing vertical displacement. Vertical offset
has also resulted in a sudden widening of drain-
age valleys as they cross from the footwall into
the hangingwall. These valley floors and the
adjacent ridge crests also show left-lateral offset
across the fault. Valley walls are offset in a left-
lateral sense by approximately 200 to 400 m.

At Ban Mai, the Thoen Fault crosses the
active floodplain of the Mae Mai River (fig. 5)
and vertically offsets an alluvial terrace surface,
down-to-the-northwest, by approximately 6 m.
The absolute age of this terrace surface is un-
known; however, from the preservation of the
terrace and the relatively immature soil devel-
opment on the terrace surface (a Bw horizon
with only limited rubification), we consider 
this surface to be Holocene in age. Assuming
approximately 6 m of vertical offset during the
Holocene, this gives a vertical displacement
rate of about 0.6 mm/yr for the Ban Mai Seg-
ment.

A road cut about 1 km west of the main
escarpment at Ban Mai (fig. 5) exposes a nor-
mal fault offsetting, down-to-the-west, a se-
quence of alluvial gravels and lacustrine clays.
The fault dips about 80°W and strikes N48°E.
Total vertical displacement exposed in the cut is
1.3 to 1.6 m. The number of events and the
amount of slip-per-event is unknown, as the top

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Recent paleoseismic investigations in Northern and Western Thailand

Fig.  7.  Development of faceted spurs produced by
episodic vertical tectonic movement. I - undissected
fault scarp. II - development of faceted spurs by
streams cutting across the fault scarp. III - period of
tectonic quiescence with slope retreat, and develop-
ment of a narrow pediment. IV - renewed fault
movement. V - dissection of the new fault scarp by
major streams and streams developed on the faces
of the faceted spurs developed at stage II. VI - a new
period of tectonic quiescence, with the development
of another narrow pediment within the footwall
block at the base of the range front. VII - renewed
fault movement. VIII - dissection of the fault scarp
produced at stage VII resulting in a line of small
faceted spurs at the base of the range front.
Remnants of narrow pediments (benches) are pre-
served at the apices of each set of faceted spurs.
Progressive slope retreat is accompanied by a
decrease in the slope angle of the faceted spurs.
Modified from Hamblin (1976).

tively inactive (Ratanasthien, 1986). The most
recent movement, therefore, appears to have
been confined to the margins of the basin along
the main Thoen Fault.

Along the Ban Mai Fault Segment, the low-
est faceted spurs are about 250 to 350 m high.
These facets themselves are not planar, but
comprise at least three beveled planes that
steepen towards the base of the escarpment.



of the section has been eroded. Young, unfault-
ed gravel (probably Holocene in age) has been
deposited across this eroded surface and is not
offset by the fault. Faulting is assumed to be
Late Quaternary in age on account of the poor-
ly developed soils both in the unfaulted unit
crossing the fault and also within the upper off-
set units. The relationship between this fault
and the main Thoen Fault is unknown. Its loca-
tion and geometry suggest that it must be a syn-
thetic fault, i.e. it has the same dip and sense of
movement as the main fault. A lack of geomor-
phic expression and the pre-Holocene offset,
however, indicates that it is less active than the
main basin-bounding fault.

With the exception of these two localities,
no other faulting is found in young deposits

along the Ban Mai Segment. The lack of ob-
served recent faulting over much of the north-
ern segment of the Thoen Fault is due to the rel-
ative absence of young deposits along the fault
trace. Where present, mainly along modern
drainage courses, these deposits are very young,
most likely less than a few thousand years old
(Woodward-Clyde Federal Services, 1996). In
addition, rice farming has extensively modified
these deposits. The high rates of erosion in
Northern Thailand result in very little aggrada-
tion along active drainages in upland regions
(Kiernan, 1991).

The 25 km long east-west-striking Doi Ton
Ngun Fault Segment forms a 300 m high range
front with well-developed triangular facets and
wine-glass canyons (fig. 5). The facets have
three well-developed bevels: the lowest is about
3 to 5 m high and dips 45°; the intermediate
bevel is about 25° to 30° and about 100 m high;
and the upper bevel is 15° to 20° and extends to
the crest of the range. The lowest bevel corre-
sponds to a prominent scarp observed on aerial
photographs (Fenton et al., 1997). All streams
crossing this fault splay show marked incision
on the footwall, indicating vertical offset. No
evidence for lateral offset is observed. With the
exception of some minor faulting and tilting of
alluvial gravels in a borrow pit at the eastern
end of this segment, no faulting was observed
in young deposits. Displacement appears to die
out rapidly westwards. The Late Pliocene-Early
Pleistocene Kho Kha basalts (Sutthirat et al.,
1995) are offset by less than 1 m, and the fault
does not appear to cut through the entire se-
quence of basalt flows.

The Mae Than Segment of the Thoen Fault
is comprised of a number of splays that strike
northeast to east-northeast (fig. 5). These splays
bound the Tertiary Mae Than Basin. The main
fault, bounding the southeastern side of the
basin, forms a 600 m high, northwest-facing
escarpment characterized by well-developed
triangular facets and wineglass canyons (fig. 6).
A well-developed bench is observed at the
apices of 280 m high triangular facets. These
facets show progressive steepening towards
their bases. Drainages crossing the fault show
extensive footwall incision, but no evidence for
lateral displacement. These drainages appear to

966

Clark H. Fenton, Punya Charusiri and Spencer H. Wood

Fig.  8. Formation of a wineglass canyon. From Wood-
ward-Clyde Federal Services (1996). 1 - Tributary drai-
nage crosses normal faulted basin margin at grade. 
2 - Normal faulting event. Tributary drainage offset ver-
tically. 3 - Drainage erodes down to new base level. 
4 - Repeated fault movement. Scarp height increases, as
does depth of slot canyon if rate of faulting is greater
than erosion.

1 2

3 4

1
2
3
4



have been ponded within the graben as shown
by the sudden widening of their respective
flood plains as they flow in and then narrow
again as they flow out of the graben. No fault
exposures were found in young alluvial depos-
its. Exposures in the Mae Than lignite mine (fig.
5) show that none of the faults on the northwest
side of the graben have been active during Late
Quaternary time.

South of Mae Than, at the base of the main
fault escarpment, at least two, possibly three,
Late Cenozoic, down-to-the-northwest fault-
ing events are preserved as stacked colluvial
wedges in a sequence of alluvial fan gravels ex-
posed in a stream cut-bank. The age of these de-
posits is unknown; however, the degree of red-
dening and cementation of these gravels almost
certainly precludes them from being Holocene.
Clasts size, mainly cobbles and boulders, is also
incompatible with the size of the present
drainages issuing from the footwall block. We
conclude, therefore, that these gravels are Plio-
Pleistocene in age. The thickness of individual
colluvial wedges, approximately 1.0 to 1.5 m,
indicates faulting events with comparable
amount throw. Assuming a similar 0.6 mm/yr
vertical displacement rate, as calculated for the
Ban Mai segment, this would suggest that the
return period for the Mae Than segment is
about 2500 years.

To the south of Sop Prap (fig. 5), some indi-
cation of the total vertical offset across the Mae
Than Segment is shown by the displacement of
a pre-Tertiary peneplain surface. Assuming the
600 to 800 m vertical displacement of this sur-
face has occurred since the initiation of normal
faulting in Northern Thailand, approximately
33 Ma (Charusiri, 1989), this gives a long-term
vertical displacement rate of 0.02 mm/yr. This
value, however, averages older, slower rates of
activity with the higher, more recent rate that
has produced the faceted spurs and wine-glass
canyons. Therefore, this slip rate must be con-
sidered a minimum value.

South of Sop Prap, the Thoen Fault steps
right and follows the base of the Doi Mae Puan
range front (fig. 5). This segment of the fault,
although marked by a linear range front, is
much more subdued than the other fault seg-
ments, suggesting that it has a lower slip rate. 

8.  Pua Fault

The Pua Fault is a 68 km long, north-strik-
ing, west-dipping normal fault bounding the
eastern margin of the Tertiary Pua Basin (figs. 3
and 9). On aerial photographs and Landsat TM
satellite imagery, the fault forms a very promi-
nent west-facing escarpment that gradually de-
creases in height and definition from north to
south. The fault has three distinct segments: the
linear northern Thung Chang Segment; the con-
cave-west central Pua Segment; and the linear
southern Santi Suk Segment (fig. 9). The most
prominent tectonic geomorphology is observed
along the northern and central segments where
the fault is marked by a steep, west-facing es-
carpment with triangular facets and wineglass
canyons. The base of the escarpment is pro-
gressively oversteepened. Drainages crossing
the escarpment are deeply incised in the foot-
wall and have little or no incision in the hang-
ingwall. Terrace fragments are preserved along
several drainages within the footwall block.
The geomorphic expression of the southern
segment of the fault is less pronounced. The
fault is still marked by a prominent oversteep-
ening at the base of the escarpment. The escarp-
ment gradually decreases in height toward the
south until the fault no longer has any topo-
graphic expression. The fault may continue to
the south for another 5 km as a prominent bed-
rock fracture striking north-northeast – south-
southwest.

The Thung Chang Segment (fig. 9) of the
fault is marked by a linear escarpment, com-
prising triangular faceted spurs and wine-glass
canyons. The facets show a marked steepening
towards the base of the escarpment and have at
least two bevels at higher elevations. The steep-
ened section at the base of the escarpment is up
to 10 m high. Where alluvial fans are better
developed, this steepening is manifest as a
warping, down-to-the-west, of the fan surface
creating low-angle (about 10 to 15°) scarps (fig.
10). A number of drainages along this segment
of the fault have been beheaded, suggesting that
there is also a lateral component of slip. The
offset of these drainages is ambiguous, thus, the
sense of lateral slip is not clear. The offsets of
terrace margins along one drainage appear to be

967

Recent paleoseismic investigations in Northern and Western Thailand



The 24 km long Pua Segment is concave to
the west (fig. 9). The central part of this fault
segment displays the highest and steepest trian-
gular facets found along the Pua Fault, and also
displays some of the best-developed wine-glass
canyons in Northern Thailand (fig. 11). This
increased definition of the fault escarpment is
coincident with a widening of the Pua Basin
(fig. 9). The base of the escarpment is over-
steepened and small terrace fragments appear to
have been stranded along tributary drainages as
a result of footwall uplift. Assuming that these
uplifted terrace fragments were formed at simi-
lar elevations to the alluvial fan surfaces within
the basin (hangingwall), then the terrace frag-
ments along the Khun and Khwang rivers have
been offset vertically by at least 50 m. The age
of these terrace surfaces, however, is unknown
and therefore they cannot be used to determine
the fault slip rate. No evidence for lateral move-
ment has been found along this segment of 
the fault. At Ban Nam Khrai, the fault again
changes orientation to a more north-northwest
strike (fig. 9) and the height of the escarpment
decreases markedly. This bend in the fault cor-
responds with an intrabasin high and it also
marks the boundary between the Pua and Santi
Suk segments of the fault.

The Santi Suk Segment (fig. 9) comprises
the most subdued topography along the Pua
Fault, although the fault escarpment displays
the same geomorphic features indicative of
active faulting found along the other two fault
segments. This segment is marked by an
escarpment that decreases in height from about
200 to 100 m over a distance of about 12 km. 
At its northern end, this escarpment has well
defined triangular facets with oversteepened
bases. The oversteepened bevel at the base of
the escarpment is about 6 m high. The low
faceted spurs at the southern end of the Santi
Suk Segment show at least three bevels, the
lowest and steepest (approximately 22°) of
which is about 6 m high. This bevel is uniform-
ly well developed along the entire Santi Suk
Segment. The age of alluvial surfaces offset by
this bevel is unknown; however, the lack of
incision and preservation of these surfaces sug-
gests that they are likely to be Holocene in age
(Fenton et al., 1997). Assuming that the bevel at

968

Clark H. Fenton, Punya Charusiri and Spencer H. Wood

Fig.  9.  Simplified map of the Pua Fault System show-
ing fault segments and localities mentioned in the
text.

right-lateral. The amount of lateral offset, how-
ever, is relatively small (< 10 m) compared with
the vertical offset. The southern end of the
Thung Chang Segment is marked by a promi-
nent fault bend where the strike of the range
front changes from north to northwest.



Recent paleoseismic investigations in Northern and Western Thailand

Fig.  10.  Low angle fault scarp on surface of Late Quaternary alluvial fan, Thung Chang Segment, Pua Fault.

Fig.  11.  Wine-glass canyon developed where the Nam Khun crosses the Pua Fault. Compare canyon profile
with fig. 8.

969



the base of the escarpment has formed during
the Holocene, this 6 m offset implies a mini-
mum vertical displacement rate of about 0.6
mm/yr. 

Further evidence for Holocene movement
on the Santi Suk segment is the exposure of a
30 m wide fault zone offsetting young soil hori-
zons developed in a sequence of alluvial grav-
els and lacustrine clays in a gravel pit at Ban
Hua Na (fig. 12). The complex nature of fault-
ing exposed in the gravel pit, involving both
normal and reverse faulting, along with the mis-
match of units across the faults suggest that
movement on the Santi Suk Segment involves 
a significant lateral component. The youngest
deposit offset by faulting is a soil horizon de-
veloped in clayey gravels, immediately below
the modern soil. Offset of this soil is about 0.3
m down-to-the-east on a west-dipping fault, i.e.
reverse movement, and about 0.5 m down-to-
the-west on a west-dipping fault. The offset soil
horizon is considered to be Holocene in age on
account of its lack of reddening and poorly deve-
loped rubification (Woodward-Clyde Federal
Services, 1996).

Although this gravel pit exposes faults off-
setting very young deposits, there are no strati-
graphic markers that can be used to determine
the amount or true sense of offset. The west-
dipping nature of these deposits suggests down-
to-the-east movement on an east-dipping nor-
mal fault, i.e. a fault antithetic to the main Pua
Fault. A short east-dipping fault is observed on
the opposite side of the basin on aerial photo-

graphs, although the geomorphic expression of
this fault does not suggest that it has been a par-
ticularly active structure.

9.  Mae Chan Fault

The Mae Chan Fault is an east-west to north-
east-southwest striking left-lateral strike-slip
fault that extends for about 140 km from Nam
Mae Chan valley in northernmost Thailand near
the border with Myanmar, across the Mekong
River and into Laos (fig. 3). Hinthong (1995)
first recognized deflected drainages, shutter
ridges, and sag ponds indicating active strike-
slip faulting. Older streams, entrenched in
bedrock, are offset by as much as 600 m 
(Wood, 2001). Younger streams channeled into
Quaternary sediments are offset by a few me-
ters. Preliminary trenching investigations indi-
cate that the most recent movement has been
Late Quaternary and possibly Holocene (Rymer 
et al., 1997).

Some of the best examples of deflected drain-
ages are found near Ban Su Fu at the western
part of the fault (fig. 13a-d). Here older, more
deeply incised streams are offset by up to 600
m, while younger, shorter streams are offset by
100 to 300 m (Wood, 2001). As well as deflect-
ed drainages, Wood (2001) also mapped a
series of offset ridge crests, creating conspicu-
ous shutter ridges and uphill-facing scarps (fig.
14a,b). Using a denudation rate for similar
regions of Southeast Asia (0.1 mm/yr), Wood

970

Clark H. Fenton, Punya Charusiri and Spencer H. Wood

Modern Soil

Pebble Gravel

Clayey Gravel

Stoneline
Fractured
Pebbles

Clayey Gravel

Clayey Gravel Clayey Sand

Modern Soil

Bedding
Pebble-Cobble Gravel

Aligned Clasts

Mottled Clay

Mottled Clay Slump

356° to 013°
vertical fractures

Numerous small fractures
with small offsets

Clay Gouge

80°/209° 73°/334°

90°/040°
90°/043°

Water seep
along fault

Mottled Clay

Buried Soil Stoneline

Modern Soil

Colluvial Wedge?

Pebble-Cobble Gravel

50 mm

20 mm

0.4 mm

0.2 mm
0.2 mm

Slump
Clayey Sand L

L

K
H

G0,8 m
K

0 5
Mottled Clay

G
0.75 m B

B
B

E

F
D

D

B

D

L

L

AA

B
B

A

C
C

L

J

Fig.  12.  Log of south-facing exposure of faulted alluvial gravels and lacustrine clays at the southern end of the
Pua Fault. Overall sense of displacement is down-to-the-west. Scale in meters.



971

Recent paleoseismic investigations in Northern and Western Thailand

Fig.  13a-d.  a) Landsat image of the Mae Chan Fault and Mekong River in northernmost Thailand. River flows
from top of image to the southwest (image processed and furnished by Michael J. Rymer, U.S. Geological
Survey, Menlo Park, California). b) Offset streams, shutter ridges, and water gaps along the Western Mae Chan
Fault. c) Detail of stream offsets near Ban Su Fu. d) Graph of offset versus stream length. One group of streams
0.5-to-0.7 km long is offset 100 to 300 m, while another group 1.1-to-1.8 km long is offset about 600 m.

c

d

a

b



(2001) calculated that a time of 200 ka is re-
quired to erode a valley extending 1.4 km into
the saprolite-mantled granitic upland south of
the fault. This assumes a trapezoid-shaped vol-
ume of sediment removed to form the valley 
60 m deep and 500 m wide at the range front.
These streams are typically offset 600 m (fig.
13d), implying a slip rate of 3 mm/yr. Because
of the many uncertainties in our geomorphic-
based estimate of valley age and fault-slip rate,
at this point in our studies we believe the slip
rate is between 0.3 and 3 mm/yr.

The Mekong River crosses the Mae Chan
Fault (fig. 13a). From the top of the image, the
river flows southward to the Golden Triangle in
a straight bedrock canyon 600 m deep that
forms the Laos-Myanmar border. Fifteen kilo-
meters north of the mouth of the Kok River the
valley floor of the Mekong River broadens to an
alluvial plain about 4 km wide. At the mouth 
of the Kok River, there is a NE-SW elongate
(14 km by 5 km) marshy depression known as
Wiang Nong that extends southwest along the
north side of the fault (fig. 13a). We interpret
this depression as a tectonic pull-apart basin or
sag consistent with left-lateral motion of the

fault. East of the mouth of the Kok River, the
river course deflects east 25 km (in a left-later-
al sense) forming two broad loops north of the
fault. The first loop is in an alluvial plain about
8 km wide, and the second is in a bedrock can-
yon about 400 m deep. The offset river then 
resumes a southerly course in the bedrock can-
yon and crosses the fault about 10 km north of
Chiang Khong, Thailand (fig. 13a). We agree
with Lacassin et al. (1998) that at this crossing
the river course appears left-laterally deflected
no more than 1.5 km. The fault has clearly af-
fected the course of the Mekong River, but we
do not know if the entire 25 km deflection is a
result of tectonic shift. At this point in our stud-
ies we do not have a detailed explanation for the
abrupt change in the river course at the mouth
of the Kok River and the s-loops north of the
fault. As the river interacted with the fault it
must have continued to flow in the canyons pre-
viously incised 300 m through the northeast-
southwest-trending ranges. If a significant part
of the 25 km deflection is tectonic, it is difficult
to explain why the actual fault crossing shows
only a 1.5 km deflection. It is possible that an
older course of the Mekong River lies to the

972

Clark H. Fenton, Punya Charusiri and Spencer H. Wood

Fig.  14a,b.  a) Ridge crest offset creating shutter ridge along the Mae Chan Fault 3 km west of Ban Su Fu. 
b) Looking north along the crest of the offset ridge crest.

a b



east on the south side of the fault, but is now
covered by a Quaternary-aged basalt field that
covers a 15-square-km area in Laos just south
of where the fault crosses the Mekong. A K-Ar
age on the basalt is 1.7 Ma (Barr and MacDo-
nald, 1981).

Lacassin et al. (1998) interpret the unusual
hairpin loops of the Mekong River crossing the
active Nam Ma Fault 60 km upriver to be the
result of Late Cenozoic slip-sense inversion. They
suggest that the Nam Ma Fault changed from a
right-lateral to a left-lateral slip at some time
between 5 and 20 Ma. They noted the 1.5 km shift
in the Mekong on the Mae Chan Fault crossing,
but did not address the larger deflection of 25 
km noted here. Slip on the order of 25 km 
since Late Cenozoic is consistent with the slip 
rate of 3 mm/yr we derived for the small streams
near Ban Su Fu. This is corresponds to the upper
bound slip rates calculated by Lacassin et al.
(1998) from river channel restoration along simi-
lar strike-slip faults to the north in Myanmar,
Laos, and Yunnan Province, China.

10.  Three Pagodas Fault

The Three Pagodas Fault Zone (TPFZ) is a
350 km long, 25 km wide, northwest-striking
zone of distributed faulting extending from 
just south of Moulmein, Myanmar, across the
Three Pagodas Pass, along the Mae Nam Khwae
Noi/Mae Nam Khwae Yai (River Kwai) drain-
age basin, and towards the Gulf of Thailand 
(fig. 15). At its northern end, the TPFZ either
merges with the Sagaing Fault system (fig. 1),
or a splay of that fault, in the Andaman Sea at
about 16°N (fig. 15). Tapponnier et al. (1982)
proposed that the TPFZ and the Mae Ping Fault
(MPFZ in fig. 1) to the north accommodated 
the majority of movement along the Malay
Peninsula during the early phase (50-20 Ma) 
of India-Eurasia collision. During this phase 
of tectonism, movement on these faults was
left-lateral, with a total offset of approximate-
ly 300 km (Peltzer and Tapponnier, 1988). Re-
cent thermochronologic studies in Western Thai-
land have revealed that this phase of left-lateral
slip ended about 36 to 33 Ma on the TPFZ
(Lacassin et al., 1997). The subsequent change

in the plate motion between India and Eurasia
causing a reversal in the rotation of Southeast
Asia initiated east-west extension across Cen-
tral and Northern Thailand (Peltzer and Tap-
ponnier, 1988). Coeval with this, movement on
the northwest-striking faults on the Malay
Peninsula reversed a right-lateral displacement.
Right-lateral movement on the TPFZ began
about 24 Ma (Lacassin et al., 1997). Earthquake
focal mechanisms in the region indicate that
right-lateral strike-slip faulting persists to the
present day (Le Dain et al., 1984).

Initial investigations of the TPFZ using
Landsat imagery concluded that the fault was
inactive (EBASCO, 1984). However, Shrestha
(1987) identified a number of suspected active
fault traces along the Mae Nam Khwae Noi
(fig. 16), including one that was claimed to 
offset an alluvial fan by 1.5 km. Hetrakul 
et al. (1991) suggested that reservoir-induced 
seismicity in the area of Khao Laem reservoir
may have occurred on a segment of the Three
Pagodas Fault. The Yunnan Seismological
Bureau (1997) identified three fault splays
along the TPFZ that have been active since
Middle Pleistocene (240-160 ka) and estimated
a slip rate of 0.19 mm/yr.

Woodward-Clyde Federal Services (1998)
carried out reconnaissance investigations of 
the TPFZ between Three Pagodas Pass and
Kanchanaburi (fig. 16). Using aerial photo-
graphs and satellite imagery and field recon-
naissance, they identified numerous geomor-
phic features indicative of active faulting,
including lateral drainage deflections, scarps on
alluvium, shutter ridges, and faceted spurs.
Between Three Pagodas Pass and Sangkhlaburi
(fig. 16), the fault has a well-defined trace only
a few hundred meters wide. South of the inter-
national border, the fault zone comprises two
parallel strands. The western strand appears to
offset a number of small streams in a right-lat-
eral manner. The amount of offset is on the
order of several meters to several tens of
meters. About 6 km north of Sangkhlaburi, the
eastern fault trace forms a prominent break-in-
slope and side-hill along the northeastern side
of a fault line valley. Streams crossing this fault
splay show a minor amount of right-lateral 
offset. 

973

Recent paleoseismic investigations in Northern and Western Thailand



At Sangkhlaburi, the strike of the fault
changes to a more north-south direction. Im-
mediately north of Khao Laem Reservoir the
fault is marked by a prominent west-facing
escarpment that steepens towards its base.
Aggradation of small alluvial fans at the base of
this escarpment and incision of the drainages
running out of the escarpment are indicative of
a component of vertical down-to-the-west dis-

placement. The northern end of this escarpment
forms a shutter ridge that deflects drainage in a
right-lateral manner.

Further south, below Khao Laem Dam, the
easternmost trace of the TPFZ forms a south-
west-facing escarpment that bounds a small
alluvium-filled basin. This escarpment displays
well-developed triangular facets with a stepped
or benched profile indicating by Hamblin’s

974

Clark H. Fenton, Punya Charusiri and Spencer H. Wood

Fig.  15.  Active faults in Western Thailand and Myanmar.



(1976) criteria that this section of the fault has
undergone episodic uplift. 

At its confluence with the Huai Mae Nam
Noi, the Mae Nam Khwae Noi is deflected in an
apparent right-lateral manner (fig. 16). Several
reaches of the river downstream also appear to
be fault controlled, as are reaches of the Mae
Nam Khwae Yai (Woodward-Clyde Federal
Services, 1998).

Over most of its length, the TPFZ is ex-
pressed in bedrock, or bedrock covered with a
thin veneer of Late Holocene alluvium. There
are very few exposures of the fault in Late
Cenozoic deposits. Along strike from a bedrock
scarp, near Rong Rian Yang Thon (fig. 16),
Plio-Pleistocene lacustrine and alluvial deposits
exposed in a gravel pit are warped and increase
in dip from 10° to 21° to the west. There is no

975

Recent paleoseismic investigations in Northern and Western Thailand

Fig.  16.  Simplified map of the Three Pagodas Fault Zone showing localities mentioned in the text. 



indication of slope movement or any other
gravitational instability, therefore this increase
in dip, beyond the angle of repose for alluvial
sediments, is most likely tectonic in origin. 

Based on deflected drainages near Sang-
khlaburi, where assumed Late Pleistocene chan-
nels are laterally displaced by up to 10 m, the slip
rate on the TPFZ is estimated at about 0.1 mm/yr
(Woodward-Clyde Federal Services, 1998). Across
the border in Myanmar, the stronger geomorphic
expression of the fault and greater deflection of
streams indicates that the slip rate may be as high
as 2 mm/yr (Woodward-Clyde Federal Services,
1998). This is similar to the level of activity ob-
served on other faults in peninsular Myanmar
(Woodward-Clyde Federal Services, 1998). 

11.  Discussion

Recent investigations have identified a
number of faults in Northern and Western
Thailand that all display evidence for Late Ce-
nozoic movement. These Late Quaternary faults
are considered capable of producing large
earthquakes. 

The Thoen, Pua, Mae Chan, and Three Pa-
godas fault zones show abundant geomorphic
and stratigraphic evidence for Late Quaternary
activity. Fault scarps on Quaternary alluvial and
colluvial deposits; vertical displacement of Qua-
ternary terrace surfaces; faulting in recent allu-
vial gravels; well-developed triangular facets
along fault escarpments with progressive steep-
ening towards the base of the escarpments; wine-
glass canyon profiles; and lateral offset of
stream courses and ridge crests are all testament
to Late Quaternary movement along these faults.
Many of these features are also found along the
Phrae, Phrae Basin, Nam Pat, Long, and Phayao
faults (Fenton et al., 1997).

The predominant displacement on the basin-
bounding faults of Northern Thailand, with the
exception of the Mae Chan Fault, is normal dip-
slip while in Western Thailand the predominant
fault movement is strike-slip. The Pua Fault and
the Ban Mai Segment of the Thoen Fault, how-
ever, show evidence for lateral displacement.
Displacement along the Mae Chan Fault in
northernmost Thailand is predominantly left-

lateral. We believe that this fault lies within a
different seismotectonic province, dominated
by strike-slip faulting. With the exception of the
Phrae Basin Fault, and small fault splays along
the Thoen Fault Zone, recent faulting has been
confined to relatively narrow zones along range
fronts (Woodward-Clyde Federal Services,
1996). This is similar to the style of faulting
that is observed in the Basin and Range Prov-
ince of the Western United States (dePolo et al.,
1991).

The structural complexity and geomorphic het-
erogeneity of these basin-bounding faults sug-
gests that, like the normal faults in the Basin
and Range Province, they are segmented. The
Thoen Fault is comprised of four segments (fig.
5). The northern (Ban Mai) segment shows a
subordinate left-lateral component of slip while
the remainder of the fault shows no apparent
lateral offset. The three remaining fault seg-
ments are defined on fault geometry (strike and
dip of the fault plane) and on the geomorphic
expression of the fault (fault scarp heights,
scarp angles, etc.); better-defined fault geomor-
phology indicates a more recently active fault
segment. The segmentation of the other faults in
Northern Thailand (e.g., the Pua Fault) is also
based on similar evidence (Fenton et al., 1997).

Although most seismicity appears diffuse
(fig. 3), Bott et al. (1997) consider that only the
1980 earthquake sequence south of Phrae and 
the 1994 Phan earthquake may be associated with
mapped faults; the Phrae and Phayao faults, re-
spectively. The Basin and Range Province in the
Western United States shows a similar relationship
between mapped faults and contemporary seis-
micity (e.g., Smith and Arabasz, 1991).

Only three focal mechanisms have been
computed to date for earthquakes in Northern
Thailand (Bott et al., 1997). These mechanisms
are consistent with the geologic data presented in
this paper, showing that this region is undergo-
ing east-west to northwest-southeast extension
on north- to northeast-striking normal or nor-
mal-oblique faults. Focal mechanisms from
Western Thailand indicate strike-slip faulting
(Le Dain et al., 1984).

The Holocene slip rates for the basin-bound-
ing normal faults in Northern Thailand range
between 0.1 and 0.6 mm/yr (table I). The Mae

976

Clark H. Fenton, Punya Charusiri and Spencer H. Wood



Chan strike-slip fault may have a slip rate as
high as 3 mm/yr, however this has not been
confirmed by paleoseismic trenching (Wood,
2001). Slip rates were calculated from the off-
set of the youngest geomorphic features or
stratigraphic units. Long-term slip rates for
these faults, calculated from the cumulative
throw across the basin margins (i.e., the sum of
sediment thickness within the basin and the
height of the range front escarpment along the
basin margin), are between 0.02 and 0.07
mm/yr. The average long-term slip rate is,
therefore, about an order of magnitude less than
the contemporary slip rate. This suggests that
the Late Quaternary has been a period of in-
creased fault activity or renewed activity fol-
lowing a period of quiescence. This is support-
ed by the presence of wineglass canyons and
downward-steepening facets along the fault 
escarpments of prominent range fronts. From
these slip rate values and the relatively rare slip-
per-event data for faults in Northern Thailand,
we estimate that the recurrence for large earth-

quakes on these faults is of the order of thou-
sands to tens of thousands of years. Slip rates
for faults in Western Thailand are less well con-
strained, but appear to be of the same order of
magnitude as those in Northern Thailand (table
I). The slip rate for the Three Pagodas Fault is
about an order of magnitude less than the re-
cently identified active strike-slip faults across
the border in peninsular Myanmar (Woodward-
Clyde Federal Services, 1998).

Maximum magnitudes estimates for each
fault are based on empirical relations between
expected rupture dimensions (Wells and Cop-
persmith, 1994). Maximum magnitude is com-
monly estimated through a comparison of fault
rupture length and magnitude. However, consid-
erable uncertainty often exists in the selection of
the appropriate rupture length to be used in the
analysis (Schwartz et al., 1984). Rupture lengths
of past surface-rupture events on a specific fault
may provide direct evidence. No such data exists
for Thailand. In the absence of definitive data to
the contrary, we conservatively assume that the

Recent paleoseismic investigations in Northern and Western Thailand

Table I. Seismic source parameters of active faults in Northern and Western Thailand.

Fault Length (1) Age of most recent Long-term Slip rate Slip-per- Recurrence Maximum
(km) movement (2) slip rate (3) (mm/yr) (4) event (5) (6) credible

(mm/yr) (m) (kyr) earthquake
(7) (M)

Long 56 Late Pleistocene 0.04 0.1 – – 7
Nam Pat 35 Late Pleistocene 0.04 0.1 – – 7
Phayao 28 Late Pleistocene 0.05 0.1 – – 7
Phrae 51 Late Pleistocene 0.07 0.1 – – 7
Phrae Basin 59 Late Pleistocene 0.07 0.1 1.2-1.5 12-15 7
Pua 68 Holocene 0.06 0.6 – – 71/4
Thoen 120 Holocene 0.02 0.6 1.0-1.5 1.7-2.5 71/2
Mae Chan 140 Holocene – 0.3-3.0 – – 71/2
Three Pagodas 350 (8) Holocene? – 0.5-2.0 – – 71/2

(1) Fault length exhibiting recent faulting.
(2) Relative age estimated from geomorphic relationships and pedologic development.
(3) Total vertical displacement across the fault (range height + basin depth) divided by time since basin opening, approx-
imately 33 Ma (Charusiri, 1989). Uncertainties on these slip rate values are at least ± 50%.
(4) Total offset of youngest geomorphic feature or stratigraphic unit divided by its relative age. Uncertainties on these
values are at least ± 50%.
(5) Determined from paleoseismic trench excavations
(6) Estimated by dividing slip-per-event by slip rate.
(7) Estimated moment magnitude from empirical relationships among rupture length, rupture area, and magnitude (Wells
and Coppersmith, 1994). Uncertainties in magnitude values are ± 1/4.
(8) Total fault length. The complex geometry of this fault suggests that it is very unlikely that the entire fault ruptures in
a single event. Maximum magnitude is based on the segmentation model of Woodward-Clyde Federal Services (1998).

977



maximum rupture length corresponds to the
maximum length of the mapped active fault trace
or trace of identified fault segments. 

Maximum magnitude estimates also are
computed based upon rupture area, which incor-
porates the maximum rupture length and maxi-
mum rupture width. The dip of the fault and
thickness of the seismogenic crust are required
to estimate down-dip width of the rupture plane.
Neither of these properties are well constrained
in Northern Thailand. However, because of the
similarities between the tectonic setting and
crustal properties of Northern Thailand and the
Western United States, we use data from the lat-
ter to estimate the dip of active faults and the
thickness of the seismogenic layer. Doser and
Smith (1989) determined that the approximate
average dip of normal faults in the interior of
the Western United States is about 60°, with a
range from about 40 to 90°. For faults in the
Northern Basin and Range Province of Nort-
hern Thailand, we used a dip of 60° ± 15° in
order to calculate rupture areas. 

Moderate-to-large Basin and Range Prov-
ince earthquakes occur at or near the base of the
seismogenic crust, and nearly all of the events
have focal depths of 15 km or less (Doser and
Smith, 1989). Many continental areas with
youthful mountains appear to be characterized
by a seismogenic thickness of 15 ± 5 km, which
corresponds with crustal temperatures less than
350 ± 100°C, the upper limit for brittle failure
and earthquake generation (Chen and Molnar,
1983). Thus, we assumed 15 ± 5 km as the
thickness of the seismogenic crust for Northern
Thailand (Bott et al., 1997).

The empirical relationships for surface rup-
ture length and rupture area used in this maxi-
mum magnitude assessment are those developed
by Wells and Coppersmith (1994). The max-
imum moment magnitude (M) for each fault is
given in table I.

12.  Conclusions

Recent geologic studies show Late Quater-
nary activity along a number of north- to north-
east-striking Cenozoic basin-bounding faults in
the Northern Basin and Range seismotectonic

province in Northern Thailand and along strike-
slip faults in the Western Highlands and Mae
Chan provinces. Geomorphic indicators of
active faulting, including fault scarps on collu-
vium/alluvium, faceted spurs, wine-glass can-
yons, linear range fronts, stream knickpoints,
and faulted Late Quaternary deposits, are 
found along six major faults in Northern Thai-
land. The sense of slip along these faults is pre-
dominantly normal dip-slip. The Pua and 
Thoen faults, however, have minor components
of lateral slip. These geomorphic data, and the
evidence from limited paleoseismic excava-
tions, show that the most recent surface ruptur-
ing events on these faults are either Late
Pleistocene or Holocene. From the slip-per-
event along the Thoen and Phrae Basin faults,
approximately 1.5 m, and the range of slip rates
calculated for these faults, we infer that the
return period for surface rupturing events on
these faults is on the order of 2500 to 15.000
years (table I). Empirical relationships between
rupture length and earthquake magnitude indi-
cate that these faults are capable of generating
earthquakes as large as M 7. Thus, like the tec-
tonically-similar Basin and Range extensional
province of the Western United States, North-
ern Thailand is characterized by faults with 
low slip rates, long recurrence intervals, and
large magnitude paleoearthquakes. The Mae
Chan Fault in northernmost Thailand and the
Three Pagodas Fault Zone in Western Thai-
land are both marked by scarps on alluvium,
deflected drainages, shutter ridges, and sag
ponds. Displacement of geomorphic features
indicates slip rates between 0.1 mm/yr to 3
mm/yr for these strike-slip faults. Based on
fault segment lengths, both of these faults are
capable of generating large, damaging earth-
quakes of up to M 71/2.

Acknowledgements

This paper arose from several seismic haz-
ards studies carried out for proposed and exist-
ing dam sites in Northern and Western Thai-
land. The financial and management support 
of the Royal Irrigation Department (RID), the
Department of Mineral Resources (DMR), and

978

Clark H. Fenton, Punya Charusiri and Spencer H. Wood



the Electricity Generating Authority of Thailand
(EGAT) are gratefully appreciated. Chaiyan
Hinthong, Apichard Lumjuan, and Suwit Ko-
suwan of DMR, and Supawan Klaipongpan 
of EGAT are thanked for facilitating these inves-
tigations and for providing stimulating discus-
sions on the tectonics of Thailand and Southeast
Asia. C. Fenton thanks his many colleagues at
URS who participated in various aspects of these
investigations. S. Wood thanks the faculty of the
Department of Geological Sciences of Chiang
Mai University for help and hospitality during
his sabbatical leave there. The efforts of Ivan
Wong and two anonymous reviewers are appre-
ciated for improving on earlier drafts of this
paper. 

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