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ORI GIN AL PA PER
Estimation of seismic hazard and risks for the Himalayasand surrounding regions based on Unified Scaling Lawfor Earthquakes
Imtiyaz A. Parvez • Anastasia Nekrasova • Vladimir Kossobokov
Received: 4 April 2013 / Accepted: 26 October 2013 / Published online: 9 November 2013� Springer Science+Business Media Dordrecht 2013
Abstract To estimate seismic hazard, the basic law of seismicity, the Gutenberg–Richter
recurrence relation, is applied in a modified form involving a spatial term:
log N M; Lð Þ ¼ A� B M � 5ð Þ þ C log L, where N(M,L) is the expected annual number of
earthquakes of a certain magnitude M within an area of linear size L. The parameters A, B,
and C of this Unified Scaling Law for Earthquakes (USLE) in the Himalayas and sur-
rounding regions have been studied on the basis of a variable space and time-scale
approach. The observed temporal variability of the A, B, and C coefficients indicates
significant changes of seismic activity at the time scales of a few decades. At global scale,
the value of A ranges mainly between -1.0 and 0.5, which determines the average rate of
earthquakes that accordingly differs by a factor of 30 or more. The value of B concentrates
about 0.9 ranging from under 0.6 to above 1.1, while the fractal dimension of the local
seismic prone setting, C, changes from 0.5 to 1.4 and larger. For Himalayan region, the
values of A, B, and C have been estimated mainly ranging from -1.6 to -1.0, from 0.8 to
1.3, and from 1.0 to 1.4, respectively. We have used the deterministic approach to map the
local value of the expected peak ground acceleration (PGA) from the USLE estimated
maximum magnitude or, if reliable estimation was not possible, from the observed max-
imum magnitude during 1900–2012. In result, the seismic hazard map of the Himalayas
with spatially distributed PGA was prepared. Further, an attempt is made to generate a
series of the earthquake risk maps of the region based on the population density exposed to
the seismic hazard.
I. A. Parvez (&)CSIR Centre for Mathematical Modelling and Computer Simulation, Bangalore, Indiae-mail: parvez@cmmacs.ernet.in
A. Nekrasova � V. KossobokovInstitute of Earthquake Prediction Theory and Mathematical Geophysics, RAS, Moscow, RussianFederation
V. KossobokovInstitut de Physique du Globe de Paris, Paris, France
123
Nat Hazards (2014) 71:549–562DOI 10.1007/s11069-013-0926-1
Keywords Himalayas � Seismic hazard � Unified Scaling Law � Seismic
risk
1 Introduction
Earthquakes constitute the most feared of natural hazards. These occur with no certain
warning and can result in great destruction and loss of life. It is understood that an
earthquake occurs when a propagating rupture suddenly releases the accumulated tectonic
stress in a system of the lithosphere blocks and faults. But it is not known with certainty,
when the rupture will occur and which of the many faults in a region will be involved. The
Himalayas and surroundings have experienced several great earthquakes of magnitude 8
and above in the past, inflicting heavy casualties and economic damage. One way to
mitigate the destructive impact of earthquakes is to conduct a seismic hazard analysis and
take remedial measures. Of course, the errors in the analysis mislead to unexpected eco-
nomic and human losses (Wyss et al. 2012).
Earthquakes are clearly very complex natural phenomena, but in this complexity, there
is also an order. The evident heterogeneity of patterns of seismicity distribution and
dynamics (Mandelbrot 1982; Keilis-Borok1990; Turcotte 1997, 1999) is apparently
scalable according to the generalized Gutenberg–Richter recurrence law that accounts for
the fractal nature of faulting (Kossobokov and Mazhkenov 1988). When epicenters are
uniformly distributed over the surface, their number will be proportional to the area,
whereas when they are distributed along a narrow strip, e.g., along a linear fault zone, the
number will be proportional to the length of a segment. There are other ‘‘fractal’’ pos-
sibilities that cannot be excluded a priori. Seismic activity is by no means a uniform
process. Therefore, the question of spatial and temporal scaling arises necessarily in
seismic hazard and risk assessment, as well as in studies of earthquake sequences prior to
the largest earthquakes aimed at earthquake prediction, which require a transfer of
estimates and/or criteria from one area to another. When the available data permit the
evaluation of the Unified Scaling Law for Earthquakes (USLE) (Kossobokov and Nek-
rasova 2003, 2005, 2007), the estimated coefficients A, B, and C could give a reliable
answer to the question.
Notwithstanding the above-mentioned difficulties, various investigators have
addressed the problem of assessing the seismic hazards in the Himalayas and sur-
roundings (e.g., Auden 1959; Gaur and Chouhan 1968; Kaila and Rao 1979; Khattri
et al. 1984; Parvez and Ram 1997, 1999; Bhatia et al. 1999; Parvez et al. 2003; Parvez
2007; Lyubushin and Parvez 2010). In this paper, we accept the hypothesis that the
seismic process is self-similar, at least locally, and estimates the coefficients A, B, and
C using the Scaling Coefficients Estimation (SCE) algorithm (Kossobokov and Nek-
rasova 2005, 2007; Nekrasova 2008; Nekrasova et al. 2011). We analyze the earthquake
catalog from USGS/NEIC and provide the maps of the A, B, and C coefficients for the
different scales and discuss their likely relationship with the observed continental
deformation and related structure of the Earth. We also discuss the usage of these
parameters in seismic hazard assessment, as well as in describing the seismicity flow
before major events in the region. Furthermore, based on the USLE-derived hazard map
and data on population, we provide some examples of seismic risk estimates for the
Himalayas and surrounding regions.
550 Nat Hazards (2014) 71:549–562
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2 Methodology
Seismic reality evidences many contradictions to the model assumption of a stationary
Poisson point process with annual rate of N(M), which according to the well-established
Gutenberg–Richter law is parameterized in a log-linear form (Molchan et al. 1997).
Eventually, a response to these leads to complications of the existing hypotheses by
introducing sequences of main events and their associates (fore- and aftershocks) super-
imposed with hypothetical distributions of the associate size, time, and location. Therefore,
estimation of N(M) at a given site of interest remains the basic source of erroneous seismic
hazard assessment (Kossobokov and Nekrasova 2012), as well as the basic source of
inadequate seismic engineering decisions (Davis et al. 2012).
The results of the global and regional analyses (Keilis-Borok et al. 1989; Kossobokov
and Mazhkenov 1994; Kossobokov and Nekrasova 2003, 2005, 2007; Nekrasova and
Kossobokov 2002, 2003, 2006; Nekrasova 2008) imply that the recurrence of earthquakes
at a seismically prone site, for a wide range of magnitudes M and sizes L [ (L-, L?), can be
described as USLE by the following formula:
NðM; LÞ ¼ 10A � 10B�ð5�MÞ � LC ð1Þ
where L 9 L is a square embedding seismic locus and A, B, and C are constants. By an
alternative formulation using the inter-event time distribution, we can denote the rela-
tionship as USLE (Bak et al. 2002; Christensen et al. 2002). The algorithm for Scaling
Coefficients Estimation, named SCE, is described in detail by Kossobokov and Nekrasova
(2003, 2005).
One can use the long-term estimates of the USLE coefficients to characterize seismic
hazard in a rather traditional terms of maximum expected magnitude and/or macroseismic
intensity, peak ground acceleration (PGA), etc. Specifically,
• Consider the values of A, B, and C obtained for grid points of a regular l 9 l mesh of
centers of the L0 9 L0 cells of interest, where L0 [ (L-, L?) is the predefined constant
used in the analysis of sizes.
• Using formula (1) for magnitude ranges from M- to M? with Dm-magnitude step
calculate the expected numbers of events in T years in the cells of interest,
NT M; L0ð Þ ¼ T � N M; L0ð Þ.• For each cell find the maximum magnitude with the expected number NT(M,L0) C p %
and assign the intensity or PGA value that corresponds to this maximum magnitude.
Presumably, the value of hazard was assigned to a cell of interest in such a way
indicates an estimate of the traditional one with the p% probability of exceedance in
T years.
2.1 Data
2.1.1 Seismic data
We consider the territory from 5�M to 40�N and from 60�E to 105�E. The coefficients of
the Unified Scaling Law for Earthquakes, USLE, are evaluated using the earthquakes
with the depth shallower than 100 km from the USGS/NEIC Global Hypocenters
Database System, 1965–2011. The choice of the threshold at 100 km is supported by the
first local minimum of the density distribution of the hypocenter depth in the region
Nat Hazards (2014) 71:549–562 551
123
considered. The magnitude attributed to each seismic event is the maximum of the
average body-wave magnitudes, mb, the average surface-wave magnitude, MS, and the
two authority magnitudes MA1 and MA2 (usually, of the MW type). There are about
5000 of magnitude 5 or larger events considered from the database of the last 47 years.
Figure 1 shows the variation of the annual number of these earthquakes in time. The
annual number is rather stable (about 100–200 events per year) before the mega-thrust
earthquake on December 26, 2004, whose epicenter, but not all aftershocks, is just
outside the region considered. Figure 2 presents the empirical density of the seismic
distribution in space evaluated in a grid of 1/2� 9 1/2� cells (the density total equals to
1). Each cell is color-coded according to the logarithm of the empirical density function.
These cells were at the base of the hierarchy of areas with linear size of 1/2�, 1�, 2�, 4�,
and 8�.
The general geological and tectonic features of the Indian subcontinent are shown in
Fig. 2a. The entire Indian subcontinent can initially be divided into three main subregions
on the basis of general geological and tectonic features. The first subregion is formed by
the Sulaiman and Kirthar mountain ranges in the northwest, the Himalayan Mountains in
the north, extending from west to east for a distance of 2,500 km, and the Arakan-Yoma
mountain ranges in the east, extending from north to south into the island arc system of the
Andaman, Nicobar, Sumatra, and Java Islands. The major tectonic features in the Hima-
layan mountain ranges include, from south to north, the main boundary thrust (MBT), the
main central thrust (MCT), and the Indus-Tsangpo suture (ITS) all along the entire length
of the Himalayas from west to east. The MBT is a series of thrusts that separates the
predominantly pre-Tertiary Lesser Himalayas from the Tertiary Siwalik, composed of
fossiliferous Riphean sediments overridden by several thrust sheets (Wadia 1975; Gansser
1977).
The MCT at the base of the central crystalline zone dips northward separating the High
Himalayas from the Lesser Himalayas (Gansser 1964). The ITS is characterized by the
ophiolite suite on the north and demarcates the northern limits of the Indian plate. The
Arakan-Yoma fold belt consists of a large thickness of Mesozoic and Tertiary rocks
intruded by granitic and ultrabasic rocks (Krishnan 1968). It is a northward continuation
0
1
10
100
1,000
1965 1970 1975 1980 1985 1990 1995 2000 2005 2010
4.0
4.5
5.0
5.5
6.0
6.5
7.0
7.5
8.0
Fig. 1 Annual number of earthquakes of different magnitude in the study region, 1965–2011
552 Nat Hazards (2014) 71:549–562
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Fig. 2 a The generalized tectonic map and location of great earthquakes of India and adjacent areas(modified after Parvez et al. 2003). b The empirical density distribution of seismic activity in space (basedon the USGS/NEIC Global Hypocenters Database System, 1965–2011)
Nat Hazards (2014) 71:549–562 553
123
into the continent of the Andaman, Nicobar, Sumatra, and Java Island arc system and is
laced with thrust zones and other faults that have been produced by the collision of the
Indian and Burmese plates (Deshikachar 1974). The fault plane solutions indicate a general
northward underthrusting of the Indian plate in the Himalayan front and an eastward under
thrusting in the Arakan-Yoma region.
The second subregion is formed by the vast alluvial plains of the river Sindhu (Indus)
and Ganga (Ganges) with an average elevation of about 200 m. The hills and coastal
plains of the Indian Peninsular shield form the third subregion with an average elevation
of about 600 m, although mountain ranges are present within this region having eleva-
tions in excess of 2,500 m. The Sindhu–Ganga basin (second subregion) is a frontal
depression that is filled by sediments and alluvium. It is also considered the replica of the
trench systems, which are associated with the front of island arc systems at subduction
zones (Khattri 1987). It consists of the autochthonous zone, in which the Precambrian
rocks of the Indian shield are down-warped and plunge under the mountains toward the
northwest, north and east forming the foredeep and marginal depression south of the
Himalayan tectonic zone. Infrequent earthquakes clustered in a few localities occur in
this subregion.
The third subregion, that is the Indian Peninsular shield, is considered to be a stable
landmass and a region of slight seismicity. The geological framework of the region is the
cumulative effect of geodynamics sequences ranging from the early Precambrian crustal
evolution to young volcanism over its northwest segment. This shield is bounded in the
north by the Narmada-Son lineament and Godavari rift system.
Figure 2a also shows the great earthquakes occurred in the past in the region, and most
significant ones are 1819 Kutch earthquake (M = 8.0), 1897 Shillong earthquake
(M = 8.7), 1905 Kangra earthquake (M = 8.0), 1934 Bihar–Nepal earthquake (M = 8.3),
1941 Andaman Island earthquake (M = 8.1), and 1950 Assam earthquake (M = 8.5).
During the last couple of decades, India had several damaging and devastating earth-
quakes, e.g., 1988 Bihar–Nepal earthquake (M = 6.4), 1991 Uttarkashi earthquake
(M = 6.9), 1993 Latur earthquake (M = 6.3), 1997 Jabalpur earthquake (M = 6.0), 1999
Chamoli earthquake (M = 6.8), 2001 Bhuj earthquake (M = 7.7), 2004 Sumatra earth-
quake (M = 9.3), 2005 Pakistan earthquake (M = 7.6), and 2011 Sikkim earthquake
(M = 6.9).
The reliable estimates of the USLE coefficients were obtained in 1,143 out of the 1,150
cells shown in Fig. 2.
2.1.2 Data on population
We consider the population density map for the territory from latitude 5�M to 40�N and
longitude from 60�E to 105�E. The population data in the present study are taken from
Gridded Population of the World (2005) that is a raster data product compiled at Center for
International Earth Science Information Network (CIESIN), Columbia University, and
Centro Internacional de Agricultura Tropical (CIAT), which renders global population data
at the scale and extent, required for demonstrating the spatial relationship of human
populations and the environment across the globe. The database provides a spatially di-
saggregated population layer that is compatible with data sets from social, economic, and
Earth science fields. We have chosen the population data estimates of the year 2010 to
assess different kinds of risk associated with seismic hazard. Figure 3 demonstrates this
population density distribution of the region.
554 Nat Hazards (2014) 71:549–562
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3 Results: estimates of seismic hazard
Figure 4 demonstrates the distribution of the estimated values for each of the three USLE
coefficients: Coefficient A represents logarithm of seismic activity; B characterizes the
balance between magnitude ranges; and C corresponds to the estimate of the fractal
dimension of seismic locus. Note that (1) unlike previous applications of formula (1), the
coefficient A is calibrated to recurrence of strong magnitude 6.0 earthquakes
NðM; LÞ ¼ 10A � 10B�ð6�MÞ � LC ð2Þ
and (2) in all the estimates of A, B, and C, the error of determination does not exceed 0.07,
confirming the claimed accuracy of the values plotted on the three maps. If we see the
distribution of coefficient A, the highest values appear in the Andaman region, northwest
Himalayas, and Pamir-Hindukush region. Figure 4b illustrates that the density bulk of the
coefficient of magnitude balance B concentrates mainly between 0.7 and 0.9, and the
higher values of B are observed in the northwest Himalayas, Hindukush, and Indo-Burmese
arc. The estimate of the fractal dimension of the earthquake epicenter locus C has a smooth
density distribution widespread from 0.8 to 1.5 and that can be interpreted as scaling along
a near linear single fault zone and the more complex structure of blocks and faults. The
highest value of C is mainly concentrated in Myanmar and Pamir-Hindukush region once
again. Evidently, the distribution of C corresponds to the level of the Earth crust disin-
tegration: Larger values of C indicate more fractured areas of the widespread zone of the
continental collision.
The USLE coefficients were used for estimation and mapping the expected maximum
magnitude M with 1 % and 10 % probability of exceedance in 50 years. For the purposes
of additional stability check and comparison, the estimation of the USLE coefficients and
the hazard maps was made also at higher resolution, but the same number of hierarchy
Fig. 3 The population density distribution (based on GPWv3 estimate for 2010)
Nat Hazards (2014) 71:549–562 555
123
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556 Nat Hazards (2014) 71:549–562
123
levels (nh = 5) and with seismic data down to magnitude 4 in 1980–2011. In particular,
the reliable estimates of the USLE coefficients (i.e., with the standard error of determi-
nation \0.05) were obtained for 1,574 cells out of the 1,640 cells of 1/4� 9 1/4� size.
Figure 5 displays distribution on the map of the expected maximum magnitude M with
1% and 10 % probability of exceedance in 50 years based on the higher resolution settings
and rich seismic data. The two distributions naturally display evident similarity and dif-
ference. Specifically, for the probability of exceedance of 1 % in 50 years, there are just 67
out of 1,143 cells (i.e., \6 %) where the estimates of the expected maximum magnitude
M differ by one half of the magnitude unit, while this number is 85 cells (i.e.,\7.5 %) for a
less restrictive probability level of 10 %. It is notable that Fig. 5 is in full agreement with
pattern recognition of the sites prone to magnitude 6.5, 7.0, 8.2, or larger earthquakes based
on geomorphologic and geodetic parameters (Bhatia et al. 1992; Kossobokov 1984), in
which validity has been confirmed by the occurrence of strong earthquakes in the region
after publications of the results (Gorshkov et al. 2003, 2012).
So far, it is not possible to use USLE estimation of the expected maximum magnitude
M at all sites, which expose seismic activity, due to the issues of spatial and temporal
completeness of earthquake catalogs for the territory under study. Therefore, for the sake
of a more comprehensive estimation of seismic hazard, we complement the final map of
the expected maximum magnitude M based on USLE with the reported maximum mag-
nitude in 1900–2010 at those cells where the USLE coefficients were not evaluated.
(Similar results were obtained using the SCE algorithm applied to the catalog of main-
shocks, although for an obvious reason of smaller sample size, the reliable estimations
were found in a smaller sample of grid points.)
The final map was used to estimate the hazard map of expected ground shaking in
terms of PGA following the semi-empirical relations given by Parvez et al. (2001). They
have used the strong motion data to determine the interdependence among the peak
ground motion, earthquake magnitude, and distance to hypocenter for the Himalayan
region. In order to produce deterministic seismic hazard map as shown in the figure, a
source–receiver distance is estimated at a grid of 0.25� 9 0.25�, and for each source of
different magnitude, PGA is calculated as in (Parvez et al. 2001): The maximum at each
cell is plotted as shown in Fig. 6. We have opted the minimum and maximum epicentral
distance at 10 and 500 km, respectively. The hazard map clearly marks the zones of high
Fig. 5 The expected maximum magnitude M with probability of exceedance in 50 years 1 % (a) and 10 %(b) (based on the USGS/NEIC Global Hypocenters Database System, 1965–2011)
Nat Hazards (2014) 71:549–562 557
123
peak ground acceleration in along the plate boundary of the Himalayas, Indo-Burmese
arc, part of Gujarat, and Andaman Nicobar region; here, PGA is shown over 1 g. In the
foothills of the Himalayas and Indo-Gangetic planes, the PGA varies between 0.06 and
0.2 g.
3.1 Estimates of seismic risks
Any kind of risk estimates results from a convolution of the hazard with the exposed object
under consideration along with its vulnerability—
R gð Þ ¼ H gð Þ � O gð Þ � V O gð Þð Þ;
where H(g) is natural hazard at location g, O(g) is the exposure of objects at risk at g, and
V(O) is the vulnerability of objects at risk. Note that g could be a point, or a line, or some
area on or under the Earth surface and that distribution of hazards, as well as objects of
concern and their vulnerability, could be time-dependent. Furthermore, the convolu-
tion � could be much more complicated operation than usually accepted as product of
terms.
Thus, there exist many different risk estimates even if the same object of risk and the
same hazard are involved. Specifically, it may result from the different laws of convolu-
tion, as well as from different kinds of vulnerability of an object of risk under specific
environments and conditions. Both conceptual issues must be resolved in a multidisci-
plinary problem-oriented research performed by specialists in the fields of hazard, objects
of risk, and object vulnerability. Here, to illustrate this general concept, we perform the
following oversimplified four convolutions of seismic hazard assessment map H(g) with
the population density distribution P:
All the four risk estimates consider the GPWv3 model population data estimates of the
year 2010 as an object of risk and use mathematical product as the convolution law. The
0.625
1.000
0.500
0.250
0.125
0.015
0.031
0.007
PGA
Fig. 6 Final deterministic seismic hazard assessment map
558 Nat Hazards (2014) 71:549–562
123
first estimate in a cell g is based on the constant equal vulnerability of an individual,
Ri gð Þ ¼ H gð Þ �R
gP, where
Rg
P is the integral of the population density over the cell g, i.e.,
the number of individuals within the area of the cell g. The second risk estimate differ-
entiates individual vulnerability in proportion to the population density at a given site,
Rii gð Þ ¼ H gð Þ �R
gP � P. This and the other two assumptions—Riii gð Þ ¼ H gð Þ �
Rg
P � P2
and Riv gð Þ ¼ H gð Þ �R
gP � P3—appear to be rather natural due to specifics of man-made
environment inflicted in the areas of high concentration of individuals, e.g., the number of
floors in a typical residential building changes with population density. The resulting maps
of the four risks in arbitrary units are given in Fig. 7. For illustration purposes, each of the
four risk scales is covering the top seven decimal orders of the risk values, so that the cells
in red are 1,000,000 times more dangerous than those in blue. The collapse of the risky
areas to the region of the densest population appears rather natural demonstrating how
nonlinearity of conditions changes expectation of seismic risk. It is notable that as
expected, the megacities and their agglomerations are at the top of risk distributions.
To avoid misleading counterproductive interpretations, we have to emphasize that the
risk estimates presented for the territory under study are given here for academic meth-
odological purposes only. They do not use complicated procedures that might be more
adequate convolutions of hazard, objects, and their vulnerability, and are used here to
illustrate the general problem-oriented approach. The estimations addressing more realistic
(c)
Riii(g)
(d)
Riv(g)
(b)
Rii(g)
(a)
Ri(g)
10
10
10
10
10
10
10
10
10
10
10
10
10
10
10
10
10
10
10
10
10
10
10
10
10
10
10
10
10
10
10
10
Fig. 7 Oversimplified convolutions of seismic hazard map H(g) with the population density distribution P:
a Ri gð Þ ¼ H gð Þ �R
gP, b Rii gð Þ ¼ H gð Þ �
Rg
P � P, c Riii gð Þ ¼ H gð Þ �R
gP � P2, and d Riv gð Þ ¼ H gð Þ �
Rg
P � P3
Nat Hazards (2014) 71:549–562 559
123
and practical kinds of seismic risks, not presented here, should involve experts in distri-
bution of objects of risk of different vulnerability, i.e., specialists in earthquake engi-
neering, social sciences, and economics.
4 Discussion and conclusion
Timings and places of earthquakes are not predictable with precision of a certain date and
rupture zone. Although it is already proven in the long-lasting global experiment that
intermediate-term middle-range earthquake predictions are reliable, accurate, and can be
effective enough to globally reduce the impact of great earthquakes from M8.0 ? magnitude
and higher ranges in advance (Kossobokov 2012; Davis et al. 2012), there is no link to
implement measures and improve earthquake preparedness in response to them. This is not
done yet, in part due to limited distribution of these predictions and the lack of applying
existing methods for using intermediate-term predictions to make decisions for taking action.
On the other hand, the general locations of earthquakes are well known globally by
earthquake monitoring and geological studies. Strong disastrous earthquakes are low
probability events that happen with certainty (i.e., 100 % probability). Long recurrence or
low probability earthquake information provided by any group as the basis for seismic
hazard assessment leads to false comfort of ignoring such rare eventualities, so that they
will happen again as unpredictable disastrous surprises. Regretfully, a systematic and
quantitative comparison of the global seismic hazard map (Kossobokov and Nekrasova
2012) discloses gross inadequacy of this ‘‘probabilistic’’ product: All 60 earthquakes with
magnitudes of 7.5 or higher were ‘‘surprises,’’ and half of them were ‘‘big surprises’’ for
the map, as well as all twelve of the deadliest earthquakes happened in 2000–2011 with the
total number of deaths exceeding 700,000 people. These and other self-evident short-
comings and failures of the widespread probabilistic approach to seismic hazard assess-
ment prove that the global map, as well as underlying methodologies, is deeply flawed. In
common sense, the map is evidently unacceptable for any kind of responsible seismic risk
evaluation and knowledgeable disaster prevention. Other modern methods for modeling
realistic scenarios of earthquakes allow better advanced seismic hazard assessment (Panza
et al. 2011).
Losses from natural hazards have continued to increase steadily due to the lack of
knowledge and poor understanding by the majority of the scientific community, as well as
by decision-makers and public, of the three components of risk, which are hazard, expo-
sure, and vulnerability. Contemporary science (geophysics and seismology, in particular) is
largely responsible for societal failures in satisfactorily coping with many challenging
changes in exposures and their vulnerabilities inflicted by growing populations, their
concentration, etc. Scientists, for their special education, knowledge, and skills, owe it to
society, which does not possess the same special knowledge and skills. Errors in seismic
hazard assessment propagate nonlinearly into unbearable errors in the expected human and
economic losses (Wyss et al. 2012).
The largest expected earthquake size for earthquake-prone locations can be realistically
estimated with high confidence. Preparing for such hazardous event ensures reduction or
even avoidance of potential disasters. Earthquakes do not kill people, but their conse-
quences, i.e., tsunamis, landslides, collapsed buildings, bridges, and other constructions,
do. The hazard scenarios for such an event estimated by deterministic computations pro-
vide the basis for necessary preparations, from land-use planning and building code reg-
ulation to emergency management. There are many risks generated by earthquakes. These
560 Nat Hazards (2014) 71:549–562
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should be not ignored in any realistic and responsible seismic risk evaluation and
knowledgeable disaster prevention.
Our study attempts to contribute modestly to an urgent revision of the seismic hazard
maps from the first principles, including (1) background methodologies and (2) imple-
mentation in assessment of seismic risks. Evidently, our contribution at this time (1) takes
into consideration economic and social factors of risk assessment in an oversimplified way,
(2) does not account for the role of site effect due to topography and soils in determining
ground acceleration, and (3) makes use of a point approximation of an earthquake rupture
even for the great and complex seismic events. These essential considerations should be
addressed in the future.
Acknowledgments The authors acknowledge the financial support from the RFBR-DST Project ‘‘Seismichazard and risk assessment based on pattern recognition: Himalayas and adjacent territories’’ (Grants RFBRNo. 11-05-92691 and DST No. INT/RFBR/P-109). We also would like to thank two anonymous reviewersfor their constructive suggestions and critical reviews to improve the quality of the manuscript.
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