articolo he.pdf


Key  words  Holocene earthquakes – Zemuhe Fault –
Southwestern China

1.  Introduction

The active Zemuhe Fault in Western Sichuan
Province, China, is a part of a left lateral fault
system, which is at least 1400 km long and ex-
tends northwest along the southeastern margin of
the Tibetan plateau. This fault system (fig. 1, thick
lines in insert), referred as the Kangding Fault
System (e.g., Molnar and Tapponnier, 1978) or
the Xianshuihe-Xiaojiang Fault Zone (e.g., Li,
1993; Wang et al., 1998), comprises five main

Holocene earthquakes on the Zemuhe
Fault in Southwestern China

Honglin He (1) (2) and Jinwei Ren (2)
(1) Active Fault Research Center, National Institute of Industrial Science and Technology, Ibaraki, Japan

(2) Institute of Geology, China Seismological Bureau, Beijing, China

Abstract
The Zemuhe Fault is a prominent active fault in Southwestern China. Seven ravines along a 5 km long fault scarp
indicate seven large magnitude earthquakes in the Holocene. The youngest four ravines were abandoned during
four large magnitude earthquakes, the age of which are constrained by radiocarbon data: ravines 7, 6, and 4 for-
med in association with the earthquakes at A.D. 1850 and A.D. 814, B.C. 4477 ± 240 or older, and ravine 5 to a
paleo-event between B.C. 4477 ± 240 and A.D. 814. Three trenches excavated by earlier workers together with
a trench excavated and analyzed here revealed 3 or 4 earthquakes, which are consistent with those indicated by
the youngest five ravines. These radiocarbon-dated earthquakes mainly occurred within two temporal clusters:
the older cluster of two paleoearthquakes occurred approximately between B.C. 4250 and B.C. 6000, and the
younger cluster includes two historical earthquakes of the A.D. 814 and A.D. 1850. Each cluster lasted about
1000-2000 years. A tranquil period of about 5000 years separates the two clusters, during which only one large
magnitude earthquake occurred. Moreover, the average recurrence interval of large magnitude earthquake in the Holo-
cene is about 1400-1700 years. Comparison of the maximum horizontal displacement of the A.D. 1850 earth-
quake, and the 85 ± 5 m cumulative lateral offset over the last 13-15 ka gives the average recurrence interval of
1000-1360 years. The different estimates may arise because moderate and small earthquakes produced a quite
high cumulative lateral displacement along the Zemuhe Fault during the Holocene.

faults: Ganzi Fault, Xianshuihe Fault, Anninghe
Fault, Zemuhe Fault, and Xiaojiang Fault. These
are amongst the most active faults in China, and
clearly deserve comparison with other highly acti-
ve strike-slip fault systems worldwide, such 
as San Andreas Fault in California, the North
Anatolian Fault of Turkey, and Alpine Fault of
New Zealand (Allen et al., 1991). Each of the
main faults has accommodated at least one large
historical earthquake. According to the local 
chronicles, the Zemuhe Fault produced two large
earthquakes of M 7 in A.D. 814 and A.D. 1850
(Huang, 1979; Gu, 1983; Chen, 1993a; Ren and
Li, 1993). 

Since the 1950’s the neotectonics, seismo-
geology and seismicity of the Zemuhe Fault
and in its surrounding area have been studied
(e.g., Southwest Investigation Team of Earth-
quake Intensity, China Seismological Bureau,
1979), and the slip rate since the last glacial

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

Mailing address: Dr. Honglin He, Institute of Geology,
China Seismological Bureau, Beijing 100029, China; 
e-mail: honglinhe@hotmail.com



1036

Honglin He and Jinwei Ren

Fig.  1. Map of the Zemuhe Fault. Thick lines indicate the fault traces, large-unfilled circles are the epicenters
of three historic earthquakes of M 7 (Gu, 1983), and the dashed ovals show the isoseismal lines of the A.D.
1850 earthquake (Ren and Li, 1993). The unfilled rectangles across the Zemuhe Fault with numbers indicate the
trench locations excavated by Fen et al. (1995), while the filled rectangle indicates the location of our trench.
Inset box shows the sketch of Tibetan tectonics and the Zemuhe Fault Zone location. Thick line is the Kangding
Fault System: 1) Ganzi Fault; 2) Xianshuihe Fault; 3) Anninghe Fault; 4) Zemuhe Fault and 5) Xiaojiang Fault.
Wide arrows indicate the movement directions of crustal blocks within the Tibetan plateau, while thin arrows
show the slip of faults. Data come from Li (1993).



epoch for the Zemuhe Fault has been reasona-
bly well constrained at 4.9 mm/yr (Ren, 1986)
or 5.8-8.6 mm/yr (He et al., 1999). The active
trace produced during the A.D. 1850 earthqua-
ke on the Zemuhe Fault was first recognized in
1985 (Ren and Li, 1989). Analysis of the fault-
scarp morphology suggests that the rupture
length of this earthquake may have been ca. 30
km (Chen, 1993a) or up to 90 km long (Ren and
Li, 1993). Trenching across the fault by Fen et
al. (1995) reveals 6 events during the Holocene,
however, these data provide an incomplete
record of earthquakes for this period of time.
Here we use data from the displacement of
dateable landforms and from trenches across
the fault to constrain the earthquake history of
the Zemuhe Fault. These data are combined
with information from an exceptionally long
historical record, and produce what we believe
a complete data set of large magnitude earth-
quakes in the Holocene.

2.  Historical earthquakes

On September 16th, A.D. 1850, a severe earth-
quake struck Xichang and its surrounding area,
resulting in the deaths of more than 23.526 peo-
ple and significant damage to infrastructure (fig. 1)
(Gu, 1983). The local chronicles show that two
other large earthquakes of M 7 also occurred in
A.D. 814 and A.D. 1536 near Xichang, and these
events can tentatively be correlated to the
Zemuhe Fault (e.g., Huang, 1979; Chen, 1993a;
Ren and Li, 1993). The A.D. 1536 earthquake
may have occurred on the Anninghe Fault (fig. 1)
(e.g., Chen, 1993b; Wen et al., 2000), while the
epicenter of the A.D. 814 earthquake was located
near the intersection of the Zemuhe and Anninghe
faults (Gu, 1983). There is no strong geological
evidence to suggest which of these two faults pro-
duced the A.D. 814 event. Based on historical
records, most researchers preferred to locate it on
the Zemuhe Fault (e.g., Ren and Li, 1989).

The epicenters of historical earthquakes in
China are defined as the center of the meizosei-
smal area (Xie, 1957). The meizoseismal area is
delineated based on the descriptions of earth-
quake damage recorded in local chronicles.
Magnitude of historical earthquake is usually

deduced from the seismic intensity in the meizo-
seismal area. Generally, both seismic intensity
and magnitude can be estimated from historical
records. Initially, the meizoseismal area of the
1850 earthquake was located at Xichang city, the
intensity in the meizoseismal area was determi-
ned to be X on the New Chinese Seismic In-
tensity Scale (Xie, 1957), and the magnitude in-
ferred to be 7.5 (Kunming Geophysics Institute,
1965 in Gu, 1983; Huang, 1979). The New
Chinese Seismic Intensity Scale was made in
1957 and revised in 1980 based on the Modified
Mercalli Scale in association with characteristics
of Chinese buildings. The two seismic intensity
scales are very similar. Historical records indica-
te that during the earthquake some damage
occurred south of the Qionghai Lake, extending
the meizoseismal area southeastward, and shif-
ting the epicenter to between the Xichang and
Ningnan (Lin and Gan, 1980). Furthermore, by
reanalyzing historical earthquake records, Huang
(1985) suggested the epicenter of this earthquake
to be south of Xichang, with intensity in the mei-
zoseismal area of X+ on the Chinese Seismic Inten-
sity Scale, and inferred the magnitude of this earth-
quake to be 7.7.

This earthquake not only produced damage to
buildings and heavy loss of life, but also produ-
ced significant deformation of the ground surfa-
ce, which was recorded in local chronicles more
than 140 years after the earthquake the surface
erosion had modified the active trace. However,
many relics of this earthquake remain and can be
identified in the field today. In 1985, the Re-
search Group of Seismic Risk in Panxi Region,
Sichuan Seismological Bureau identified a 30 km
long rupture of this earthquake from south of
Qionghai Lake to the Tuomugou (Chen, 1993a),
and estimated the magnitude to be 7.5. In con-
trast, Ren and Li (1993) suggest a 90 km long
rupture from Lijianbao to Songxin (fig. 2) with a
maximum lateral displacement of 7 m (fig. 3),
and a modified pattern of isoseismal lines (dash-
ed ovals on fig. 1). They located the epicenter of
the earthquake near the Daqing village, south of
Qionghai Lake, and proposed M 8 based upon the
rupture length and maximum displacement. 

Based on our fieldwork in 1997 and 1998, we
concur with the conclusions of Ren and Li (1993)
for the reasons shown below.

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Holocene earthquakes on the Zemuhe Fault in Southwestern China



1)  We have identified a number of tectonic
features between Daqing and Qiaowuo (figs. 1
and 2), such scarplets, fault trough, sag pond, off-
set landform, fissure and filled wedge, etc., as the
landforms observed by Ren and Li in 1985 and
1986 (Ren and Li, 1993).

2)  At Lijinbao village north of the Qionghai
Lake (figs. 1 and 2), a fissure created in the A.D.
1850 earthquake, which is filled by a wedge of
material, was described by Wu (1982). We named
this kind of wedge-like filled material as filled
wedge. Although no rupture phenomenon was
found near the Xichang city presently, many land-
slides and fissures are recorded in the local chroni-
cles. These fissures and landslides may be largely

absent today because of intensive human activity,
which has resulted in landform modification.

3)  Near Songxin village (figs. 1 and 2) to the
south a series of scarplets and tensional fissures
were observed, which are arranged in a left-step-
ping en échelon pattern. The height of these scar-
plets ranges from 0.3 m to 6 m, and the depth and
width of these tensional fissures from 0.5-10 m
and 1-10 m, respectively.

4)  Along the rupture zone, lichen samples
(Caloplaca sp. and Acarospora sp.), taken from
the fault scarp or from talus in 9 sites including
the scarplets and tensional fissures mentioned a-
bove, were dated at between 114 ± 46 and 164 ±
± 35 years BP (Ren, 1986). These data suggested
that most of the observed fault-scarp was produ-
ced during the A.D. 1850 earthquake.

In addition to these two large historical earth-
quakes, there were 10 moderate earthquakes of 
5 M < 7 recorded on the Zemuhe Fault since A.D.
116 (Gu, 1983). Of these moderate size earth-
quakes, five events are between magnitude 5 and 6,
and the other five between magnitude 6 and 7. 

3.  Paleoearthquakes recorded by the offset 
of ravines along the fault scarp

The Daqingliangzi uplift is the watershed
between the Anninghe River Basin and the Ze-
muhe River Basin (fig. 1). Along the Zemuhe
Fault, uplift has produced a 5 km long fault
scarp (fig. 4a,b). The fault scarp reveals that the
uplifted region comprises the Daqing Forma-

1038

Honglin He and Jinwei Ren

Fig.  2. Map of surface rupture associated with the A.D. 1850 earthquake. Thick lines show the location of the
active trace, while the thin lines show the drainage of the Zemuhe River. 

Fig.  3. Near the Sijiabushi village a 50 cm wide fis-
sure due to the A.D. 1850 earthquake offset sini-
strally a small pressure ridge by 7 m, view to north.



tion gravel of Late Pleistocene age. Daqing
Formation principally consists of pebbles deri-
ved from purple-gray quartz sandstone and
rhyolite of Sinian age. The diameters of the
pebbles vary between 18 and 35 cm. The sou-
theast dip of imbricated pebbles in the lower
layer of the gravel suggests a paleo flow direc-
tion of Zemuhe River to the northwest towards
Qionghai Lake in the early Late Pleistocene
(Huang, 1979). It further suggests that the
Daqingliangzi uplift started to grow no earlier
than the Late Pleistocene. The height of the
fault scarp decreases gradually from north to
south, and diminishes at the bend in the high-
way near Sijiabushi (fig. 4b). In the north, the
scarp height is about 40 m and its slope is about
50°, however, these values changes to 20 m and
70° in the south. The 0.5-2 m high surface rup-
ture produced by the A.D. 1850 earthquake
developed along the base of the northern seg-

ment of the fault scarp, and it merges with, and
cannot be differentiated from, the fault scarp in
the south. 

Seven ravines are cut into the top of the Da-
qingliangzi uplift, on the upthrown eastern side
of the fault scarp (figs. 4b and 5). The average
length of these ravines is about 1000 m, and the
width varies between 15 and 20 m. Ren measu-
red the geometry of the features of these ravines
in 1986 (table I). We suggest that formation of
the fault scarp not only resulted in abandon-
ment of the ravines across the top of the Da-
qingliangzi uplift, but also separated the mod-
ern Zemuhe River into two branches. The
eastern branch flows on the east of the uplift,
whereas the western branch flows along the
base of the fault scarp. East of the uplift all of
these ravines are occupied by streams which
flow southeastward into the eastern branch.
West of the fault scarp on the downthrown wall

1039

Holocene earthquakes on the Zemuhe Fault in Southwestern China

b

a

Fig.  4a,b. 5 km long fault scarp from Daqing to Sijiabushi (location shown in fig. 2). a) A pair of air photo-
graphs; b) field photograph, view to east.



of the Zemuhe Fault, there are several minor
streams flowing southeastward into the western
branch (figs. 4a and 5). Ravines on the eastern,
upthrown, side of the fault are all much deeper
and wider than those on the downthrown wall,
suggesting much greater flow in those ravines.
Moreover, the ravines are all parallel to, and simi-
lar in shape to, the modern channel segment of
the western branch north of Sijiabushi, which
flows eastwards at the southern end of the fault
scarp (figs. 4b and 5). These data suggest that
the ravines were, in all probability, cut by the
main channel segment of the western branch,
and later we hypothesize that they were aban-
doned due to repeated uplift events on the fault.

The geomorphologic expression of these
ravines indicates that the northern ravines are
older than the southern ravines. The most
direct expression is that slope angle and depth
of the northern ravines are less than those of
the southern ravines (table I). The three nor-
thernmost ravines (1 to 3 from north) on the
Daqingliangzi uplift are subtle features and
not easily identifiable. These ravines are shal-
low troughs with gentle (less than 10°) side-
slopes, which are indicative of significant
post-abandonment erosion of the ravines. The
shape of the southernmost four ravines (4 to 7)
is characterized by steep walls. The steep bank
slopes of the southernmost four ravines also
suggest that the ravines young from north to
south (table I). 

1040

Fig.  5. Map of the fault scarp, offset ravines and drai-
nage system on the top of the Daqingliangzi uplift.
Thick line is the fault scarp with ticks on the downth-
rown side of the fault. Thin lines show the drainage
system. Gray zones show the ravines; the grayscale
from dark to light show the age of ravines from young
to older. Arrows in the gray zones indicate the follo-
wing directions. Black squares indicate the locations
of the C14 samples.

Table  I. Slope angle of the bank and the depth of the seven ravines.

Southern slope Northern slope D (m)
As Ls (m) Hs (m) An (m) Ln (m) Hn (m) (Hs + Hn)./.2

1 ca. 5

2 10° 61 10.6 7° 45 5.5 8.1

3 12° 64 13.3 10° 39 6.8 10.1

4 44° 31 21.5 25° 17 7.2 14.4

5 55° 30 24.6 30° 22 11.0 17.8

6 60° 15 12.9 40° 30 19.3 16.1

7 72° 14 13.3 45° 21 14.9 14.1
As, and An are angles of the southern and northern slopes; Ls, and Ln are lengths of the southern and northern
slopes; Hs, and Hn are heights of the southern and northern slopes, Hi = Li * tan Ai (i = s, n); D is the depth of
ravine, D = (Hs + Hn)./.2.

Honglin He and Jinwei Ren



Fig.  6. Sketch showing the evolutionary scenario of
ravines on the top of the Daqingliangzi uplift formed
in association with large magnitude earthquakes on
the Zemuhe Fault.

All of these ravines are cut into, and post
date, gravel of the Daqing formation of Late
Pleistocene age. A layer of yellow colored
loess-like silt soil occurs on the top of the
Daqingliangzi uplift. Since loess-like silt layer
envelopes the three northernmost ravines, the
Daqing formation gravel is not exposed. This
suggests that the northernmost ravines 1-3 for-
med after deposition of the Daqing formation
gravel and the change in flow patterns of the
Zemuhe River, but before deposition of the
loess-like layer. In the floor and sides of ravines
4-7 the Daqing formation gravel crops out and
the gravel of the modern river is exposed and
identified in the bottom of ravines 6 and 7. This
suggests that ravines 4-7 must have formed
after deposition of the loess-like silt.

We therefore propose that the ravines for-
med in sequence from north to south across the
top of the Daqingliangzi uplift and that shifts in
the position of the active stream channel were
triggered by uplift during large magnitude
earthquakes (fig. 6). In the early part of the Late
Pleistocene, the Zemuhe River flowed north-
ward into the Qionghai Lake (Huang, 1979),
while in the latter part of the Late Pleistocene it
changed its flow direction from northward to
southward. After the change in river course, the
Zemuhe River flowed as a single channel, flo-
wing along the present-day eastern branch with
a series of small tributaries flowing into the
channel from each side. Formation of the fault
scarp during large magnitude earthquakes re-
sulted in the abandonment of small tributaries,
which formally crossed the Daqingliangzi
uplift. The water from these abandoned minor
tributaries subsequently flowed southward a-
long the base of the fault scarp, and produced
the western branch of the Zemuhe River. The
newly formed western branch changed flow
direction from southward to eastward at the
southern end of the fault scarp producing a new
channel or occupying a preexisting minor tribu-
tary. During each large magnitude earthquake, the
fault scarp extended southward, uplifting the
area east of the fault and forcing western branch
further south around the fault scarp. Simulta-
neously, the old eastward flowing segment of
the western branch was uplifted and abando-
ned, producing a ravine immediately north of

Holocene earthquakes on the Zemuhe Fault in Southwestern China

1041



the active channel. Therefore, the recurrence of
large magnitude earthquake on the Zemuhe
Fault is interpreted to produce the ravines on
the top of the Daqingliangzi uplift (figs. 4b, 5
and 6). For such a model seven large magnitude
earthquakes could produce the observed ravines.

The evolutionary model outlined above is con-
sistent with the southward decrease in Daqin-
gliangzi uplift. As a result, the fault scarp is a
cumulative vertical displacement along the higher
in north than in the south. We postulate that each
ravine was abandoned due to episodic tearing 
of the fault during large magnitude earthquakes.
Therefore, the time of abandonment of each ravi-
ne may indicate the date of each large magnitude
earthquake. The dating of three C14 samples, ta-
ken in ravines 4, 6 and 7, implied the ages of
three earthquakes corresponding to ravines 4, 6
and 7 (table II, samples’ location shown in fig. 5).

Of all of the ravines the southernmost one is the
most similar in shape to the modern river channel
at the southern end of the uplift. The difference bet-
ween the two is that many trees and shrubs are gro-
wing on the two side-slopes of the latter, while the
former contains many dead roots and trunks with
little vegetation. These many dead roots and trunks
in the southernmost ravine should have been gro-
wing before abandonment; their death is due to
abandonment. A piece of a dead root (R7 in table
II) taken from the floor of ravine 7 was radiocar-

bon dated as younger than 200 years BP. Based
on this date, we infer that ravine 7 was abando-
ned during the A.D. 1850 earthquake. At the
floor of ravine 6 two hundred meters east of the
fault scarp we observed a piece of paleo-flood
plain. On the paleo-flood plain covers a layer of
dark brown peat. We infer that the peat layer
developed in a mash pond after abandonment. A
sample (R6 in table II) taken from the dark
brown peat layer was radiocarbon dated at 745 ±
± 85 years BP, implying that this ravine was aban-
doned at some time older than A.D. 1279 ± 123.
There is no historical record in local chronicles
of an earthquake in this region near A.D. 1279 ±
± 123. We consider it unlikely that an earthquake
of the magnitude as large as the A.D. 1850 event
would not be recorded in local chronicles had it
occurred near A.D. 1279 ± 123. Therefore, we
hypothesize that ravine 6 was abandoned during
the A.D. 814 earthquake and that the young
radiocarbon age may indicate that some of the
dated carbonaceous material accumulated in the
ravine well after abandonment. Near the fault
scarp on the base of northern convex slope of
ravine 4 found a layer of black peat, which has
been radiocarbon dated at 5615 ± 115 years BP
(R4 in table II). Also considering the black peat
layer developed in a mash pond in the ravine
after abandonment, we can infer another earth-
quake event have occurred at, or older than B.C.

1042

Table  II. Radiocarbon data.

No. Location Material C14 age (years BP) Cal age (yr)# Lab.

R7 Ravine 7 A piece of wood < 200 < A.D. 1750 Lab. 1 (1)
R6 Ravine 6 Peat 745 ± 85 A.D. 1279 ± 123 Lab. 1 (1)
R4 Ravine 4 Peat 5615 ± 115 B.C. 4477 ± 240 Lab. 1 (1)

Tro-1 Our trench A piece of wood 3150 ± 100 B.C. 1422 ± 216 Lab. 1 (2)
Tr1-1 Trench 1 Wood fragments 500 ± 100 A.D. 1412 ± 119 Lab. 2 (3)
Tr1-2 Trench 1 Wood fragments 1200 ± 120 A.D. 828 ± 211 Lab. 2 (3)
Tr1-3 Trench 2 Peat 3612 ± 106 B.C. 1969 ± 243 Lab. 2 (3)
Tr2-1 Trench 2 Peat 5528 ± 95 B.C. 4386 ± 167 Lab. 2 (3)
Tr3-1 Trench 3 Wood fragments 670 ± 145 A.D. 1259 ± 235 Lab. 2 (3)
Tr3-2 Trench 3 Peat 6700 ± 155 B.C. 5602 ± 244 Lab. 2 (3)
Tr3-3 Trench 3 Peat 12.015 ± 216 B.C. 11.979 ± 462 Lab. 2 (3)
Tr3-4 Trench 3 Wood fragments 4993 ± 137 B.C. 3778 ± 270 Lab. 2 (3)

Lab. 1 - New Date Laboratory, Institute of Geology, CSB; Lab. 2 - Sichuan Seismological Bureau. # - Calculated
by CALIB Radiocarbon Calibration (Vision 4.3). (1) Ren (1986); (2) this study; (3) Fen et al. (1995).

Honglin He and Jinwei Ren



4477 ± 240. In addition to the three inferred
events occurred at A.D. 1850, A.D. 814 and B.C.
4477 ± 240 or older, four more events might be
indicated by the observed ravines. For such a
scenario the large magnitude earthquake that
resulted in abandonment of ravine 5 would date
at between A.D. 814 and B.C. 4477 ± 240. The
remaining three ravines are inferred to be older
than B.C. 4477 ± 240, and also older than the
loess-like silt. The silt has not been dated and we
suggest that ravines 1-3 are most likely to be
early Holocene in age. This would require seven
large magnitude earthquakes on the Zemuhe
Fault in the last 10 kyr.

4.  Paleoearthquakes recorded in trenches

Five hundred meters south of the southern
end of the fault scarp a stream is offset in a left-
lateral sense by about 85 m. On the eastern side
of the fault the stream has been abandoned and
formed a relict tail-cut stream. A new alluvial fan
has formed on the eastern side of the fault and
a small gully has been displaced left-laterally
by 16 m (fig. 7a). North of the abandoned tail-
cut stream a small pressure ridge is developed
on the eastern side of the fault (fig. 7b), pro-
bably due to a slight right step of the fault tra-
ces. North of the small pressure ridge, we exca-
vated a 10 m long, 1.5 m wide and 2.5 m deep
trench (location shown by a filled box across
the Zemuhe Fault in fig. 1, and a unfilled box in
fig. 7b). Based on mapping of the trench the log
was divided into 15 units (fig. 8). 

This trench revealed two earthquakes of
the Zemuhe Fault. It is, however, difficult to
identify the displacement of each event,
because no sedimentary layers could be corre-
lated across the fault surface on the trench log.
The wedge deposits of unit 2 and unit 8 are
likely to indicate the two seismic events.
Figure 9 presents a possible scenario of the
events in the trench. The older event displaced
and flexed sediments of unit 10 to unit 15
(stage 2). After this event, a colluvial wedge
(unit 8) was deposited in the depression for-
med by the flexure. The younger event cut this
colluvial wedge and dragged the peat sedi-
ment of unit 7 down (stage 4). Another wedge

deposition (unit 2) was formed after the second
event.

A piece of wood (Tro-1 in table II) enclosed
by sediments of unit 11 to unit 14 was radio-
carbon dated at 3150 ± 100 years BP. This da-
ting result indicates that unit 11 is, or older than
B.C. 1422 ± 216. The fault trace does not reach
the ground surface, and the sediments of units 2
to 6 are not displaced. Moreover, the 90 km long
surface rupture of the A.D. 1850 earthquake was
found to go through east of the trench along the
fault scarplet (fig. 7b; Ren, 1986). We therefore
infer that the two events interpreted in this trench
should have occurred in the period between B.C.
1422 ± 216 and the A.D. 1850 earthquake, and
the younger one may be consistent with the A.D.
814 earthquake. 

On the same section of the fault that we
trenched, Fen et al. (1995) excavated four tren-
ches in 1995 (locations shown in fig. 1, unfilled
boxes across the Zemuhe Fault with numbers).
Because the timing of paleo-events in the sou-
thernmost trench was not constrained by dating
(trench 4), we only use data derived from the
remaining three trenches.

Trench 1 was excavated north of the Daqing
village across the fissure zone formed in the A.D.
1850 earthquake. This trench revealed a multi-
fissure zone, which is filled by three wedges of
different materials. Two C14 samples of wood
fragments (Tr1-1 and Tr1-2 in table II) taken
from the two youngest filled wedges produced
dates of 500 ± 100 years BP and 1200 ± 120 years
BP. The newest stratum, which is cut by the
boundary fault of the oldest filled wedge, is ca.
1.5 m thick light yellow sediment of silt with
pebbles. In the middle of the stratum there is a
thin peat layer of ca. 1.75 m long and 5 cm
thick, which was radiocarbon dated at 3612 ±
±106 years BP (Tr1-3 in table II). If the three fil-
led wedges resulted from three seismic events,
the three seismic events should all be younger
than B.C. 1969 ± 243. If the wood fragments
taken from the two youngest filled wedges died
prior to being incorporated into the wedges, the
event corresponding to the newest filled wedge
should be the A.D. 1850 earthquake (younger than
A.D. 1412 ± 119), and the event corresponding to
the middle filled wedge should be A.D. 828 ±
± 211, which is consistent with the historical

1043

Holocene earthquakes on the Zemuhe Fault in Southwestern China



Honglin He and Jinwei Ren

Fig. 7a,b. a) Geomorphologic map of Zemuhe Fault (location shown in fig. 2). Fault scarp is marked by the
thick line; ticks are on the downthrown side of the fault. Eighty-five-meter lateral displacement of abandoned
stream is shown. Contour data (10 m intervals) are from 1:50 000 topographic maps. b) Detailed map of part of
fault. Topographic contours of 1 m were constructed from surveying and the thick lines with teeth show fault
scarplet and the rupture of the A.D. 1850 earthquake.

b

a

1044



earthquake of A.D. 814. The oldest event recor-
ded in this trench must be younger than B.C.
1969 ± 243. These conclusions are similar to
inferences from our trench (fig. 8).

Trench 2 crossed a scarplet of the A.D. 1850
earthquake. This trench revealed five fault sur-
faces (F1, F2, F3, F4, and F5) and a colluvial
wedge. Although Fen et al. (1995) proposed that
there are five seismic events recorded in this
trench, only four of these events, including the
1850 earthquake, are unambiguously represen-
ted (fig. 10). The oldest event is indicated by
F1, which is covered by the colluvial wedge.
The sediment layer displaced by F1 was dated
at 5528 ± 95 years BP using a sample of peat
taken from this layer (Tr2-1 in table II). This
implies that the oldest event is younger than
B.C. 4386 ± 167. The colluvial wedge, which
occurs in the northeast of F2 and covers F1,
demonstrates an earthquake younger than the
oldest event. A sediment layer was deposited
over the colluvial wedge and F2, F3. The fault
surface F4 cut into this sediment layer and indi-
cates another event younger than the two events
noted above. The newest event is the A.D. 1850
earthquake that produced a modern scarplet
(F5) and a sag pond northeast of the scarplet.

Trench 3, which is about 100 m south of our
trench, also crossed a fissure of the 1850 earth-
quake. Fen et al. (1995) identified six events in
this trench, but in our opinion two of these
events are equivocal. The remaining four events
in this trench will be summarized here (fig. 10).
A multi-fissure zone filled by two wedges of
different materials and two fault surfaces (F1
and F2) within the trench we interpreted to have
formed in four earthquakes. The younger filled
wedge is composed of yellow sandy silt, from
which a sample of wood fragments (Tr3-1 in ta-
ble II) was dated to be 670 ± 145 years BP. Con-
sidering that the wood fragments possibly died
hundreds of years prior to being incorporated
into the wedge, we infer that the younger filled
wedge formed after the A.D. 1850 earthquake
(much younger than A.D. 1259 ± 235). The
older filled wedge is composed of gray sandy
silt including some pebbles. A sample of peat
taken from the older filled wedge (Tr3-2 in
table II) was dated to be 6700 ± 155 years BP.
This radiocarbon date demonstrates another
earthquake occurred at B.C. 5602 ± 244 or
older. The event indicated by the fault surface
F1 is the oldest one revealed in this trench. A
peat sample (Tr3-3 in table II) taken from the

1045

Holocene earthquakes on the Zemuhe Fault in Southwestern China

Fig.  8. Log of the southern wall of the trench excavated by us for this study. The location of the trench is shown
in figs. 1 and 7b. 1 - Light yellow boulder gravel bed; 2 - mixed deposit wedge of gray soil and gravel; 3 - dark
brown soil used for cone cultivation; 4 - black peat lens in unit 3; 5 - black peat bed; 6 - brown humus-rich silt
bed; 7 - black peat bed; 8 - deposit wedge of sand gravel; 9 - black peat bed like unit 7, but having poor strati-
fication; 10 - dark brown humus-rich silt bed, thicker than unit 6; 11 - light yellow gravel sand bed with rich pie-
ces of root and root hair; 12 - black peat with rich pieces of root and root hair; 13 - yellow sand bed with rich
pieces of root and root hair; 14 - dark brown humus-rich silt bed with rich pieces of root and root hair; 15 - gray
gravel-bearing sand bed, its top layer has rich pieces of root and root hair.



Honglin He and Jinwei Ren

Fig.  9. A possible history for the trench in fig. 8, giving 5 stages, in which stage 2 and stage 4 correspond to
two large magnitude earthquakes.

1046



surface of F1 was dated to be 12.015 ± 216
years BP. If inferring that the peat formed in
surrounding sediment before and was drawn
onto the surface of F1 during this oldest earth-
quake, the oldest event should be younger than
B.C. 11.979 ± 462. Another layer of sandy gra-
vel deposited over the fault surface F1 was cut
by another fault surface F2. This sandy gravel
was dated to be 4993 ± 137 years BP using
wood fragments (Tr3-4 in table II) taken from
the gravel. The event indicated by F2 should be
therefore younger than B.C. 3778 ± 270.

5.  Discussion

The radiocarbon dates indicate four large
magnitude earthquakes since some time older
than B.C. 4477 ± 240, which were associated
with the formation of the southernmost four ra-
vines (4-7). The trench we excavated recorded
two earthquakes, probably in the period from
B.C. 1422 ± 216 to A.D. 1850, in addition to the
latest historic earthquake of A.D. 1850. The
three trenches excavated by Fen et al. (1995)

suggest three, four and five events. We summa-
rize these results as in fig. 10. 

Although the trench data are incomplete in
the Holocene, it is likely that the seven events for
the ravines include all large magnitude earth-
quakes as strong as the A.D. 1850 earthquake or
A.D. 814 earthquake. Of the seven large magni-
tude earthquakes, the trenches reveal the youn-
gest five. The paleoearthquake younger than
B.C. 3778 ± 270 revealed in trench 3 is an inde-
pendent event, no relation to any large event
indicated by ravine data (fig. 10). Considering
the inference that the seven events for the ravi-
nes are all large magnitude earthquakes of the
Zemuhe Fault in the Holocene, we suggest this
paleo-event younger than B.C. 3778 ± 270 is a
moderate earthquake. Moreover, trench 3 recorded
a Late Pleistocene earthquake younger than
B.C. 11:979 ± 462. Seven large magnitude
earthquakes indicated by ravine data suggest an
average recurrence interval of large magnitude
earthquakes on the Zemuhe in the Holocene of
about 1400-1700 years. However, collectively
the trench and ravine data indicate that the re-
currence interval of large magnitude earthqua-

1047

Fig.  10. Seismological history of the Zemuhe Fault based upon historic and paleoseismological data. Tr1, Tr2
and Tr3 are three trenches excavated by Fen et al. (1995), Tour is the trench excavated by us in 1997. Arrow
with left direction show the upper age limit of paleoearthquakes, while arrow pointing rightwards indicates the
lower age limit of paleoearthquake. The unfilled arrow indicates that the seismic event dated by radiocarbon
sample is actually a historical earthquake. Dark gray rectangles show the errors on the radiocarbon dating.
Question marks within dark gray rectangles indicate an inferred paleoearthquake without dating. Double-arrow
shows temporal cluster of seismic activity. Light gray rectangles show preferred ages for the paleoearthquakes;
thin vertical lines shows possible age bound of the paleoearthquake, while dashed line shows no age bound of
the paleoearthquake. 

Holocene earthquakes on the Zemuhe Fault in Southwestern China



kes in the Holocene along the Zemuhe Fault is
not uniform (fig. 10). Except for the oldest two
Holocene large paleoearthquakes with no radio-
carbon date, the remaining five large radiocar-
bon-dated events present obviously two temporal
clusters. The older cluster occurred between B.C.
4250 and B.C. 6000 including two large magni-
tude earthquakes (large events 4 and 5), and the
younger cluster since A.D. 814 including histori-
cal earthquakes of A.D. 1850 and A.D. 814. The
recurrence interval in the older cluster is similar
to the average, 1400-1700 years, while the recur-
rence interval in the younger cluster is only 1000
years, shorter than the average. The two temporal
clusters are separated by a tranquil period of
about 5000 years, during which only one large
magnitude earthquake (large event 3) occurred.

The majority of Quaternary sediments in the
Zemuhe River valley deposited during defor-
mation were derived from a local source. Local
transport of these sediments resulted in the for-
mation of three river terraces the Zemuhe River
valley (T1, T2, and T3 from low to high). The

most extensive terrace is the lowest (T1) (fig.
11), which consists of a unitary deposit of boul-
der gravel with a sand and mud matrix. The
sizes of framework boulders range from sever-
al centimeters to several meters. This gravel is
polymictic, comes mainly from the following
sources: 1) Sinian-age purple sandstone, tuff,
conglomerate, and gray dolostone and limesto-
ne; 2) Triassic-age gray quartz sandstone and
limestone, and 3) Jurassic-age purple sandsto-
ne. Fresh exposures of the gravel are light pur-
ple because most of the source rocks are pur-
ple. A silt and fine sand sample, taken from the
lowest terrace (about 1 m deep), has been dated
at 13.290 ± 104 years BP using a thermolumi-
nescence method (He et al., 1999). Ren (1986)
radiocarbon dated a piece of wood in the terrace
deposit to be 15.630 ± 990 years BP. Therefore,
the lowest terrace (T1) is estimated to have in
the last glacial epoch, about 10-15 kyr BP. Be-
tween Sijiabushi and Tuomugou, we have measu-
red five offsets of streams or creeks at four sites
(85 m, 88 m, 80 m, 90 m and 80 m), which are

1048

Fig.  11. Map showing the fault trace and terraces of the alluvial fan in the Zemuhe Valley between Sijiabushi
and Tuomugou. Five offsets of streams developed on the alluvial fans of the first terrace (T1) have been measu-
red at four sites. Three boxes above show detailed offsets of streams.

Honglin He and Jinwei Ren



cut into the lowest terrace (T1) (fig. 11).
Therefore, the average 85 ± 5 m offset is younger
than the formation of the lowest alluvial fan ter-
race, and was produced by a series of earthquakes
since the last glacial epoch. The maximum lateral
displacement in the A.D. 1850 earthquake was
identified to be 7 m (fig. 3). Eleven to thirteen
large magnitude earthquakes with lateral displa-
cement of 7 m would be required to produce 85±
± 5 m cumulative offset. The average recurrence
interval would be 1000-1360 years. This result
is shorter than 1400-1700 years estimated by
historic earthquakes and dated paleoearthquakes.

Regardless of the error of the radiocarbon
dating, the fact remains that quite a high part 
of total accumulated displacement along the Ze-
muhe Fault was probably not produced by large
magnitude earthquakes. We infer that quite a
large part of total accumulated displacement a-
long the Zemuhe Fault was accommodated by
moderate and small earthquakes. According to
the local chronicles, 10 moderate earthquakes
of magnitude between 5 and 7 have occurred on
the Zemuhe Fault since A.D. 116 (Gu, 1983).
Trench 3 reveals a moderate paleoearthquake
younger than B.C. 3778 ± 270, which should
have produced surface rupture. The Xiaojiang
Fault, another active fault of the Kangding Fault
System as the Zemuhe Fault (inset in fig. 1), has
similar features. The average recurrence inter-
val estimated using the rate of strike slip is less
than that estimated from paleoearthquake data
(Shen et al., 1997). Shen et al. (1998) proposed
a model similar to ours to explain this kind of
difference of recurrence intervals.

Table I shows the geometric features of
those ravines on the top of the Daqingliangzi
uplift. The depths of the ravines are all greater
than the 5 m maximum vertical displacement of
the 1850 earthquake (Ren, 1986) and the depths
of the Zemuhe River channel or other nearby
streams. This suggests much stronger river ero-
sion on the Daqingliangzi uplift than nearby area.
We infer the much stronger river erosion is cau-
sed by the vertical displacement of the Daqing-
liangzi uplift during those moderate earth-
quakes. Therefore, we improve the evolutionary
model proposed above as fig. 6 shows. Initial-
ly, the Western Zemuhe River channel flowed
southward along the fault scarp and turned to

east around the southern end of the fault scarp
(fig. 12a). Secondly, small displacement during
moderate and small earthquakes occurred.
These displacements were not large enough to
force the eastward flowing channel segment to
be abandoned, but were sufficiently large to
produce river down cutting. Simultaneously
these displacements make the fault scarp exten-
ded southward (fig. 12b). Thirdly, when a large
magnitude earthquake occurred, it contributed
slip to the fault scarp and resulted in southward
extension of the western Zemuhe River chan-
nel. A new eastward flowing channel segment
developed at the new southern end of the fault
scarp; the old eastward flowing channel seg-
ment at the old southern end of the fault scarp
was abandoned simultaneously (fig. 12c). 

6.  Conclusions

In this paper we describe and summarize
earthquakes on the Zemuhe Fault recorded by
abandoned ravines along an uplifted fault scarp,

Holocene earthquakes on the Zemuhe Fault in Southwestern China

Fig.  12a-c.  Model to illustrate the development the
Daqingliangzi fault scarp and ravines on the scarp
top. .L and d are the horizontal and vertical offsets
during large magnitude earthquakes; .La and the
depth of the abandoned ravine da are the horizontal
and vertical offsets accommodated by moderate and
small earthquakes.

1049

a

b

c



by paleoearthquake recorded in trenches and by
examining historical records. Seven abandoned
ravines on the Daqingliangzi fault scarp are in-
terpreted to indicate seven events as large as the
A.D. 1850 earthquake or A.D. 814 earthquake.
The youngest four earthquakes were radiocarbon
dated at A.D. 1850, A.D. 814, B.C. 4477 ± 240 or
older, and between B.C. 4477 ± 240 and A.D.
814, while the older three are only inferred. The
seven events indicated by seven ravines should be
all the large magnitude earthquakes in the
Holocene. The trenches excavated by previous
workers and by us reveal 2-4 earthquakes in the
Holocene, most corresponding to those demon-
strated by youngest five ravines on the Daqin-
gliangzi uplift. We conclude that the average
recurrence of large magnitude earthquake on the
Zemuhe Fault in the Holocene is about 1400-
1700 years, with a minimum of about 1000 years.
In detail, however, recurrence intervals were
variable with clusters in the Holocene. The first
cluster occurred between B.C. 4250 and B.C.
6000, and the second younger than A.D. 814.
Each cluster lasted for about 1000-2000 years.
Between the two clusters, there was a long tran-
quil period of about 5000 years, during which
only one large magnitude earthquake (correspon-
ding to ravine 5) occurred. Furthermore, using
the maximum horizontal displacement of the
A.D. 1850 earthquake and the 85 ± 5 m cumula-
tive lateral offset that accrued over the last 13-15
ka, we inferred another average recurrence of
1000-1360 years, shorter than 1400-1700 years.
This difference may arise because moderate and
small earthquakes produced a quite high part of
cumulative lateral displacement along the
Zemuhe Fault during the Holocene.

Acknowledgements

We thank Mr. Song Fangmin, Ms. Zhang
Wanxia and Dr. Li Chuanyou for their kind 
help in field investigation. We are grateful to Dr.
Kenji Satake for his constructive criticism of the
manuscript. Thanks are also due to Dr. A. Nicol
for critical reviews that greatly improved this
paper. Honglin He acknowledges the financial
support partly by the SASAKAWA Scientific
Grant from the Japan Science Society. 

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Holocene earthquakes on the Zemuhe Fault in Southwestern China



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