A rate-state model for aftershocks triggered

by dislocation on a rectangular fault:

a review and new insights

Rodolfo Console and Flaminia Catalli

Istituto Nazionale di Geofisica e Vulcanologia, Rome, Italy

e-mail: console@ingv.it, e-mail: catalli@ingv.it

November 2005

Submitted to Annals of Geophysics



Abstract

We compute the static displacement, stress, strain and the Coulomb failure stress produced in

an elastic medium by a finite size rectangular fault after its dislocation with uniform stress drop

but a non uniform dislocation on the source. The time-dependent rate of triggered earthquakes

is estimated by a rate-state model applied to a uniformly distributed population of faults whose

equilibrium is perturbated by a stress change caused only by the first dislocation. The rate of

triggered events in our simulations is exponentially proportional to the shear stress change, but

the time at which the maximum rate begins to decrease is variable from fractions of hour for

positive stress changes of the order of some M P a, up to more than a year for smaller stress

changes. As a consequence, the final number of triggered events is proportional to the shear

stress change. The model predicts that the total number of events triggered on a plane con-

taining the fault is proportional to the 2/3 power of the seismic moment. Indeed, the total

number of aftershocks produced on the fault plane scales in magnitude, M , as 10M . Including

the negative contribution of the stress drop inside the source, we observe that the number of

events inhibited on the fault is, at long term, nearly identical to the number of those induced

outside, representing a sort of conservative natural rule. Considering its behavior in time, our

model does not completely match the popular Omori law; in fact it has been shown that the

seismicity induced closely to the fault edges is intense but of short duration, while that expected

at large distances (up to some tens times the fault dimensions) exhibits a much slower decay.

Key Words: aftershocks, earthquake triggering, fault parameters, rate-and-state, Omori law.

1 Introduction

Studying the space-time interaction of earthquakes is important not only for the comprehension

of earthquakes, but also for its possible application to the assessment of seismic hazard.

In this paper we revisit the physical modeling of the interaction between seismic events,

seeking a relationship between the source parameters of an earthquake and the rate of all

other earthquakes that follow it. The results obtained from the simulations performed with

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the physical model proposed in this study are not totally innovative; however, they are rarely

taken into account by the numerous studies concerning the fault interaction and earthquake

triggering.

A purely statistical approach to this phenomenon exists with the name of ”epidemic model”

(Ogata, 1988, 1998; Console et al., 2003). In the epidemic model each earthquake source

is supposed capable of increasing the probability of new earthquakes according to a spatio-

temporal kernel representing the probability distribution, which is decreasing from the causative

source. The epidemic model is applicable not only to the aftershock phenomenon but also to

the foreshock. However, despite it provides an accurate statistical representation of earthquake

interaction, the physical interpretation is neglected.

In order to formulate a more physical description of clustered seismicity, we consider that

seismic events modify the stress field around the causative fault. Our main goal in this work

is to observe the spatio-temporal variation of the seismicity rate after an event introducing in

the algorithm a rate-state model approach derived by Ruina (1983) and Dieterich (1986, 1992,

1994). In particular, we seek a physically based relationship between the magnitude of the

causative earthquake and the number of its aftershocks. Some recent studies put in evidence

that sudden stress variations, even of small magnitude, can produce large variations of the

seismicity rate. It is recognized as a phenomenon of triggering on faults that are already loaded

by tectonic stress and in close-to-failure condition. The seismicity rate increases in general

where the stress change (called Coulomb Stress Change) is positive, according to the Coulomb

model (Mendoza and Hartzell , 1988; Boatwright and Cocco, 1996; Stein et al., 1997; Gomberg

et al., 1998, 2000; Harris, 1998; King and Cocco, 2001; Stein, 1999; Toda and Stein, 2000;

Kilb et al., 2002; Belardinelli et al., 2003; Nostro et al., 2005). These studies were able to give

a physical interpretation for earthquake interaction observed in specific real cases, but were

not suitable for the general application of the model in predictive way that can be tested for

example using the information contained in a seismic catalog. In particular, the Coulomb stress

change criterion does not allow to model the hyperbolic time decay of the aftershock rate after a

mainshock, known as the Omori Law. In this simple model all the impending earthquakes would

be clock-advanced by a constant time that depends on the stress change and on the loading

3



rate but does not depend on the physical properties of the fault (Gomberg et al., 1998). The

experience shows that the Earth does not rather behave in this way. The most popular empirical

description of the phenomenon is the Omori law, stating that the aftershock rate decays in time

as t−1. Among the various theories modeling the Omori law, we have taken in consideration

only the one that assumes the rate-and-state dependent constitutive model of faults. We have

considered only the static stress changes created by an earthquake. We have not considered,

even without rejecting them in principle, other hypotheses that predict a time variation in

stress, like viscoelastic relaxation or the diffusion of fluids in the crust. The rate-state model

for earthquake nucleation seems capable of substantially explaining all the phenomenology. In

this model a promoted failure does not occur instantaneously at the exceeding of a threshold

stress as for the Coulomb-Amonton criterion, but follows a more complex non-linear time history

with different phases. This time history depends on the physical properties of the fault too.

Gomberg et al. (2005) have shown that the rate-state Dieterich model may be derived from

simple general ideas. The application of the rate-and-state model to the evolution of seismicity

is not new; Toda et al. (1998) have used this model to predict the spatio-temporal seismicity

rate after the Kobe earthquake. Other examples of application of the same model can also be

found in the literature (Toda and Stein, 2000, 2002, 2003). Following the rate-state model it

has recently been possible to simulate seismicity quite realistically, accounting for the rate of

events triggered by stress changes even at large distance from the inducing earthquake (Ziv ,

2003; Ziv and Rubin, 2003).

Basing our work on the classical theory of the elasticity, we start from the formulation of

the stress released by a rectangular fault with uniform stress-drop; then we apply the rate-state

model (Dieterich, 1994) obtaining the complete time and space distribution of the seismicity

induced by a given earthquake. It is important to remark that for present purposes we neglect

the interaction between subsequent events, supposing that only the first event perturbs the

stress field. We also neglect the effect of the free surface of the Earth. In this study we focus

our attention on the behavior of induced seismicity in space (on the fault plane) and time and

its relationship with the fault’s parameters. The results of simulations are analyzed to find out

the scaling relationships existing between the free parameters of the model and the expected

4



seismicity in a way that will allow the validation of the model by real observations.

2 Elastic model for a rectangular fault

The theoretical approach of this work has been made as simple as possible, still preserving the

capability of modeling the stress transfer from a seismic source to another.

Suppose that a fault is embedded in a homogeneous, isotropic, elastic medium where the

stress tensor σ is uniform. At a particular moment, the fault slips generating an earthquake,

and suppose that the earthquake fully releases the component of the traction parallel to the slip

vector across the fault. We call ∆σ (the stress drop) the uniform negative change of traction

on the fault. It is well known that the slip distribution on a fault in similar conditions is not

uniform. The slip distribution will satisfy the theory of the elasticity at the new equilibrium,

and it will be zero on the edges of the fault. It is also well known that the shear stress on the

fault plane outside the edges of the fault increases significantly.

The analytical solution for the slip distribution on a fault at the equilibrium does not

exist except that for very simple geometries, such as a rectangular fault of constant width and

infinite length (Knopoff , 1957) and for a circular fault (Keilis-Borok , 1959; Udias, 1999). As

mentioned by Kostrov and Das (1998), the analytical solution is not known even for a geometry

as simple as a rectangular shape of width W and length L. In the literature it is possible to

find the computation of the stress field generated by an ideal rectangular fault with uniform

slip in an infinite homogeneous space or half-space (Chinnery, 1961; Iwasaki and Sato, 1979;

Okada, 1985, 1992). However, as mentioned above, this is not a realistic model since it implies

the com-penetrability of the medium at the edges of the slip region. For this reason, here we

make use of a non uniform slip distribution that is approximatively compatible with a uniform

stress drop on the fault.

To calculate the static displacement, stress and strain, we start from the Somigliana Tensor

and we make use of the double couple point source elastic theory. We compute the modified

Coulomb failure stress from the relation:

σc = Ts + µ
′Tn, (1)

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where Ts and Tn are respectively the traction parallel to the slip vector and the traction normal

to the fault plane (negative for compression); µ′ is the effective coefficient of friction incorpo-

rating the pore fluid pression that is commonly assumed to be proportional to normal stress

change (although this assumption is not general, see Cocco and Rice (2002)). The effective

coefficient of friction in coseismic stress change studies has varied from 0.0 to 0.75, with an

average value of µ′ = 0.4 often used. This is the value we have used in our simulations.

Our model of an extended source is drawn heuristically from that of a rectangular fault

infinitely extending in one direction and that of a circular fault, and it is characterized by a

slip distribution as:

∆u =
∆σ

µ

√√√√[( W2 )2 − x2] [( L2 )2 − y2]
LW
4

, (2)

defined for −W/2 ≤ x ≤ W/2 e −L/2 ≤ y ≤ L/2, where x, y are the coordinates on the fault

plane whose origin is coincident with the center of the rectangle, ∆σ is the stress drop and µ the

shear modulus (rigidity) of the elastic medium. Equation (2) satisfies the condition of zero slip

on the edges of the rectangle. The slip distribution is of a form very similar to that obtained

numerically by Kostrov and Das (1998) with the finite differences method. Its analytical form

is similar to the solution for a circular fault. Moreover, for a fault of square shape (W = L) it

achieves a seismic moment consistent with those obtained analytically for two circular faults,

respectively inscribed and circumscribed to the square. Bonafede and Neri (2000) have shown

that, when imposing a unidirectional traction release in the strike or dip direction, a minor

component of slip is present, over the fault plane, even in the direction perpendicular to the

released traction. We have neglected this component.

For our numerical applications we discretize the continuous slip distribution of equation (2)

with a set of point sources densely and uniformly distributed on the fault. The more numerous

are the point sources, the more accurate will be the approximation.

In our numerical simulations, we arbitrarily, but without loss of generality, suppose that

the fault is on the (x1, x3) plane. Let us notice that some fault parameters are connected among

each other; in particular, the scalar moment M0 is defined through the relation:

M0 = µ∆uW L =
π2

16
µ∆umaxW L =

π2

32
∆σ(W L)3/2, (3)

6



where ∆u is the average slip on the fault and the maximum slip, ∆umax, is defined as:

∆umax =
∆σ

µ

√
LW

2
. (4)

We also assume that the magnitude M is proportional to the logarithm of the seismic moment

M0 (measured in N m) according to the Kanamori and Anderson (1975) relation:

log M0 = 9.1 + 1.5M. (5)

The computer code allows the user to chose among several options: - The focal mechanism

characterizing the causative fault and the induced events constrained by the strike φ, the

dip δ and the rake λ angles; - Dimensions and stress drop, seismic moment, or magnitude

of the causative fault; - Type of output: displacement (3 components), stress or strain (6

independent components), traction parallel to the slip vector and perpendicular to the fault

plane (2 component) and Coulomb failure stress (1 component).

The output values are given on a rectangular grid of points, whose orientation (horizontal,

or vertical parallel to one of the co-ordinate axes), dimensions, and spacing are also selected by

the user. See Figure 1 for the conventions we adopted for the reference system and the angles.

In this work we make, for sake of simplicity, the assumption that all the aftershocks have

the same focal mechanism of the causative earthquake.

Figure 2 shows the component of the stress field σ12 parallel to the slip calculated through

the parameters listed in Table 1. Note that this figure shows the stress change and not its

absolute value.

Figure 2 clearly shows that the shear stress σ12 is maximum near the edges of the fault, in

particular along the slip direction x1, and decreases with increasing the distance from the fault.

Inside the fault the stress change is negative and approximately equal to the imposed value of

−∆σ.

3 The rate-state model

As already stated, we assume that the time-dependent behavior of the seismicity triggered by a

shear stress change in a population of faults is described by the rate-state model introduced by

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Dieterich (1992, 1994) where the constitutive model proposed by Ruina (1983) and Dieterich

(1986) is used. According to this model the rate R of earthquakes due to a ∆τ shear stress

perturbation is given by:

R =
r τ̇

τ̇r[
τ̇
τ̇r

exp
(
−∆τ
Aσ

)
− 1

]
exp

(
−t
ta

)
+ 1

τ̇ 6= 0, (6)

whose various parameters are defined in Table 2. Note that equation (6) does not account for the

magnitude of the earthquakes, for the distribution of which we assume the classical Gutenberg-

Richter frequency-magnitude relationship. However, both R and r refer to the number of

earthquakes in a specific magnitude range.

We make the assumption τ̇ = τ̇r. The meaning of this assumption is that the primary

earthquake does not change the long-term stress rate due to the tectonic driving forces in the

environment.

It is easily understandable from (6) that the integral of R over infinite time diverges. This

is due to the fact that the limit of R for t → ∞ is the background rate r. We prefer to deal with

the net triggered seismicity rate R′ = R−r. The plot of R′ versus time for different values of ∆τ

is shown in Figure 3 (see also Dieterich (1994)). It shows that the initial value of the triggered

seismicity rate, immediately after the triggering event, is proportional to the exponential of

the stress variation but the time period over which R(t) is maximum and relatively constant

decreases exponentially by the same factor for increasing shear stress change. This time period,

in substantial agreement with Dieterich (1994), can be obtained computing the intersection

between R′(t = 0) and the straight line corresponding to the limit of R′ when ∆τ → ∞. The

difference with Dieterich (1994) is that we have preferred to make use of R′, rather than R,

and we ignore the case τ̇ = 0 which we judge not realistic. Such time period ranges from few

hours for a variation ∆τ = 5M P a to nearly one year for ∆τ = 1M P a. Figure 3 finally shows

that the total duration of the triggered seismicity is the same but the shape of the decay is

different for different ∆τ .

The integration of R′ over infinite time leads to the not completely trivial result that the

total number of triggered events in an area of constant stress change is proportional to ∆τ :

8



∫ ∞
0

R′(t)dt =
rta
Aσ

∆τ =
r

τ̇
∆τ. (7)

This relationship, predicted by the friction model, had been observed for ”Landers After-

shocks” by Gross and Kisslinger (1997).

Consider the integral over time of the triggered seismicity rate R′, once for a positive ∆τ ,

and then for a negative ∆τ of the same size, and we sum the two functions. We obtain a

quantity that initially has a positive increase and then tends back to zero (Figure 4). This

result can be interpreted as a sort of conservative law of the seismicity, by saying that the

expected total number of aftershocks generated in a place close to a fault can be balanced, at

long range, by the total number of those events that are inhibited by the stress drop in a place

internal to the fault if the stress drops are equal in absolute value. It seems to us that this

circumstance has been ignored, so far, in all previous studies on this subject.

For numerical applications it is necessary to define the value of the various parameters

appearing in equation (6). Table 3 contains a list of values inferred from several geophysical

considerations and used in our simulations. The reference seismicity rate, r, is a quantity that

should be known experimentally for a given area, and it is related to the average strain rate τ̇

of that area. We use for r a uniform value of four events of magnitude exceeding 3.0 per year

per 1000 km2, and for τ̇ a value of 5 KP a per year. These are simplifications of the reality

where r and τ̇ are not geographically uniform. These parameters seem however reasonable for

an area of moderate seismicity. The reason why r is expressed as a number of events per unit

area and time is given below. The parameter A of the constitutive law has a value ranging from

0.005 to 0.015 obtained from laboratory experiments (Dieterich, 1995). Generally, simulations

that most nearly resemble earthquakes in nature were obtained with rather small values of A,

near to A ≈ 0.001. The value of Aσ has been evaluated for different sequences of earthquakes

by several authors (Stein, 1999; Belardinelli et al., 2003). The parameter σ is the normal stress

on the fault (of the order of some tens of M P a). The characteristic time of aftershocks, ta,

depending on the other parameters through the relation ta = (Aσ)/τ̇ , in this context is of the

order of several tens of years. This value is essential to model a long term triggered seismicity,

because the effect of the stress change disappears completely after a time of the order of the

9



double of ta.

4 Application to a rectangular fault

Dieterich (1994) discussed in detail the case of a finite circular dislocation with uniform stress

drop. In our simulations we have taken into consideration a vertical, rectangular strike-slip

fault embedded in an infinite, homogeneous, isotropic, elastic medium. The values assumed for

the fault parameters are again those reported in Table 1. Assuming a constant stress drop ∆σ,

the scalar seismic moment M0 is proportional to the quantity (W L)
3/2, that can be considered

a sort of equivalent source volume. Scaling W and L by a given factor, M0 scales accordingly,

and also the shape of the stress distribution in space scales by the same factor. Assuming that

the background seismicity rate is given as the number of events per unit volume and time,

and integrating over the space, we find that the number of events triggered by the earthquake

is proportional to the source volume, i.e. to the seismic moment M0, or to 10
3
2
M , where M

is the magnitude. In this study we analyze only those aftershocks occurring on the fault

plane neglecting off-fault seismicity and assuming that this is the plane of weakness optimally

oriented with respect to the tectonic loading stress. The modeling of the space-time distribution

of seismicity triggered by an earthquake is straightforward, introducing the expression for the

Coulomb failure stress σc in equation (6) for ∆τ considering that on the fault plane σc ≡ ∆τ .

In fact, on the fault plane, the normal stress changes in a homogeneous and isotropic medium

are likely to vanish.

In this case, the number of triggered events would be proportional to the fault area of

the triggering event and then to M
2/3
0 , or to 10

M . If this scaling is true, one earthquake of

magnitude M would have a number of aftershocks ten times larger than one earthquake of one

magnitude unit smaller. Assuming, then, that the b value of the Gutenberg-Richter frequency-

magnitude relation is equal to 1, it would follow that the earthquakes of magnitude M , all

together, produce the same number of aftershocks as the earthquakes of one magnitude unit

smaller. This hypothesis is supported by the statistical analysis of real observations (Utsu,

1969; Yamanaka and Shimazaki, 1990; Felzer et al., 2001; Helmstetter , 2003; Helmstetter et al.,

2005) and will be used in the following of the paper.

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A first group of simulations concerning the seismicity triggered by a fault as a whole have

been performed to study the variation of the total number of triggered events (in space and

time), Ntot, versus the main free source parameters: the stress drop ∆σ, the linear dimensions

L and W and the magnitude M .

Tables 4, 5 and 6 show the results obtained assigning a fixed value for one of the parameters

at a time, and letting the others change according to equations (3) and (4). These simulations

have been carried out by summation of the single contributions of the elementary cells con-

stituting the area surrounding the fault. Only the seismicity triggered on the fault plane, but

outside the fault edges, has been considered. Looking at Table 4 one can notice that, under

our hypotheses, for a constant stress drop, the total number of triggered events increases about

proportionally to the fault area LW . Theoretically it should be exactly proportional to the

area of the source, but in the calculations there are numerical imprecisions due to the grid size

approximations. These numerical simulations show, also, that the number of aftershocks is

proportional to the 2/3 power of the scalar seismic moment or to the exponential of the mag-

nitude (10M ), in agreement with the above theoretical arguments. Table 5 clearly shows the

proportionality existing between the stress drop ∆σ and Ntot, having fixed the linear dimensions

of the fault. This is a simple consequence of the proportionality between the stress drop, ∆σ,

and the shear stress change, ∆τ , at any point of the space around the source; furthermore, it

is an example of the proportionality expressed in equation 7 between ∆τ and the total number

of triggered events, integrated on the whole space. The results reported in Table 6 give credit

to the hypothesis that, for a constant magnitude, the earthquakes of smaller linear dimensions

generate a larger number of triggered events. Indeed, a point source would yield the largest

quantity of triggered events for the same magnitude.

Let us mention, lastly, the results of a simple numerical test. We just have theoretically

shown in the previous section that the total number of events triggered by a stress change ∆τ

per unit area is, after a time much larger than the characteristic time ta, identical to the number

of events inhibited by a negative shear stress change −∆τ on the same area. The numerical

simulations about an extended source, with parameter still shown in Table 1, reflect this idea

in a more general way. In fact, if we take the total number of aftershocks produced in a time

11



interval of 100 years by a fault of 100 km2 on the portion of an area of 104 km2 external to

it, we find 353.2 events, while the same computation made including the negative contribution

of the area internal to fault itself gives only 15.6 (less than 5%). The idea of an overall null

balance is, then, substantially met: the phenomenon of clustering does not change the long

term seismicity rate of a large area. This is in contrast with the opinion that trigger zones

produce many more shocks than are missing from the shadows (Toda and Stein, 2003). We

nevertheless regard for Marsan (2003) that put in evidence the practical difficulty to observe

in nature the lack of events (the quiescence) mainly when looking at weakly active regions and

short timescales.

5 Temporal behavior of the triggered seismicity

Let us now consider in more detail the dependence on time of the number of triggered events

predicted by the present hypothesis. Kagan and Jackson (1991) and Dieterich (1994) found, in

their empirical works, that shallow aftershocks, above a given magnitude cutoff, decay globally

(for different distance intervals) in about 10 years and this time decay appears to systematically

decrease with increasing depth. In our model the behavior in different zones depends on the

different values of the stress changes, that decrease with the increasing distance from the edges

of the fault. It can be then noted that the plateau of the plot of the seismicity rate versus

time (see Figure 3) has a duration that increases with the increasing distance from the source.

This result depends on our assumption of considering only aftershocks on the mainshock fault

plane. It can also be biased by the fact that we consider only the effect of the static stress

step ∆τ caused by a mainshock and we neglect the interaction between others events. We also

do not account for heterogeneities of frictional or constitutive properties nor for the dynamic

stress concentration at the crack tip. In spite of that, we believe that our model can describe

a behavior not so far from reality. Therefore we keep as our reference the model of fault given

in Table 1 again.

As shown in Figure 5a, in the close neighboring of the fault (within 0.5 km from the

perimeter of the fault), most of the aftershocks occur within one day after the occurrence of the

inducing earthquake, and more than 1/3 of them occur already in the first hour. This is clearly

12



not the case for further distance from the source: in the slice between 0.5 and 8.5 km from the

fault, about half of the activity is exploited within about one year. The further we go apart

from the source, the longer is the time interval necessary for the exploitment of the triggered

activity. In fact, in the distant zone (from 20 to 100 km from the fault) most of the triggered

events occur longer than 20 years after the inducing earthquake (Figure 5b). The behavior

shown in Figure 5a and 5b is illustrated also by the snapshots of the spatial distribution of

the seismicity rate at different times. Figures 6, 7 and 8 clearly show how the distribution of

aftershocks resembles that of the stress change (Figure 2) and how the time decay is different

in the different slices. These also show how shadow zones (where the seismicity is inhibited)

have an effect longer in time. It should be noted again that we make the assumption that the

aftershocks occur mainly on the fault plane and that these have the same focal mechanism of

the causative event.

We are now interested to check if the generalized Omori law is suitable to describe the

temporal behavior of R′(t) predicted by our model in every spatial slice and, in such case,

by means of which free parameters. We refer to the generalized Omori law as to the formula

describing the decay of aftershock rate after a mainshock (Utsu et al., 1995) through three free

parameters a, c e p:

R′(t) =
a

(c + t)p
. (8)

For this purpose we make use of an algorithm for the least squares best-fit of the sets of data

reported in Figure 5 by the integral of (8) over the time:

y =

∫ t
0

R′(t′)dt′ = a

[
(c + t)

1−p − c1−p

1 − p

]
. (9)

The results obtained for the best-fit are shown in Table 7. It is evident that the values of

the parameters obtained are quite different from case to case (for instance, the c parameter is

extremely small for the slices closest to the fault edges), and that the standard deviation is

larger for the slices that include the wider range of distances from the fault. These results show

that the same set of parameters in equation (9) can not fit the synthetic values obtained for

different zones. Dieterich (1994) reached a similar conclusion for a source model represented by

a circular shear crack. However, his analysis was limited to the spatial variation of p parameter

letting c = 0. The observation that the Omori p parameter varies spatially in real aftershocks

13



sequences has been documented not only by Dieterich (1994) but also in a number of papers

(Wiemer and Katsumata, 1999; Wiemer , 2000; Enescu and Ito, 2002; Wiemer et al., 2002;

Wiemer and Wyss, 2002). Wiemer et al. (2002) reported a case of significantly different c

values in the northern and southern Hector Mine aftershock volume, respectively. Enescu and

Ito (2002) in their study of aftershock activity of the 2000 Western Tottory earthquake found

c-values very close to 0 except for larger magnitude earthquakes, arguing that this feature could

result from incompleteness of data, or might also reflect the complexity of the rupture process.

The situation is illustrated also by the plots of Figures 9 and 10, showing the graphical

comparison between the synthetic data and the relative theoretical approximation for different

slices.

6 Conclusions

In the development of this model some approximations have been made. Two of the most

important are (a) having neglected the dishomogeneity of the stress drop on the fault, and

consequently the very complicated pattern of slip (this must certainly have influence on the

aftershock pattern: some aftershocks may even occur inside the fault, where the gradient of

slip is high); (b) having neglected the interaction between subsequent events.

The first step of our modeling, concerning the stress change in the medium following an

earthquake, has given results comparable to those of previous papers as, for instance, Chinnery

(1961) and King and Cocco (2001). This substantial agreement, though the simplifications

introduced in this specific case of rectangular source, supports the validity of our methodology.

Neglecting the interaction among seismic events and using the rate-and-state model of

Dieterich (1994) entails that the total number of triggered events per unit area is proportional

to the shear stress change. Nevertheless, the time constant by which the rate of events decreases

has a large variability, ranging from a fraction of hour for a shear stress change of several M P a,

up to tens of years for stress variations smaller than 1 M P a.

A first set of simulations carried out with a model of rectangular fault, based on the

hypothesis that most of the aftershocks occur on the same plane of the fault, has lead to

the relationship between the main source parameters and the number of triggered events. The

14



simulations lead to the conclusion that many earthquakes of small magnitude can produce,

in total, a number of aftershocks comparable to that of fewer larger earthquakes. Our model

predicts, in fact, that, for a constant stress drop, the number of triggered events is roughly

proportional to the seismic moment at the power of 2/3, or equivalently to 10M , as observed

in various occasions. Helmstetter (2003); Helmstetter et al. (2005) suggest that this behavior

can be related to the fractal structure of the spatial distribution of the seismicity and to the

nature of earthquake interactions. For a costant stress drop we also observe that the total

number of triggered events is proportional to the area of the fault; on the other way, if the

linear dimensions of the fault are kept constant, the number of triggered events is proportional

to the stress drop.

An important aspect of the model concerns the time-space behavior of the triggered seis-

micity. The simulations show that the application of the rate-state model and equation (6)

introduced by Dieterich (1994) to the static model of stress change has as a consequence some-

thing more complicate than the conventional Omori law for the temporal decay of aftershock

rate. In fact, the seismicity is expected to be intense (in accordance to the stress change) and

have a maximum constant value, close to the fault edges of the primary earthquake, but the

time necessary for the starting of decay is shorter. On the contrary, the seismicity expected

at larger distances (up to 10 times the linear dimensions of the fault) is weak, but the time

necessary for the decay from the maximum value is longer (even some tens of years). We can

conclude that the temporal behavior of aftershock rate varies in space. Moreover, the model

predicts that the total long term production of aftershocks, including wider areas, is not negli-

gible respect to the short term production. In this respect, the regional background seismicity

could be interpreted as a sort of noise, or memory, due to the superposition of the effect of many

older earthquakes. The time decay described by the popular Omori law could be interpreted as

an apparent average result of the contribution from the various areas on the plane containing

the primary fault.

The rate-state model (Dieterich, 1994) used in our algorithm for the time distribution of the

seismicity produced by a dislocation on a rectangular fault, has allowed a partial justification

of the Omori law. We outline the following main conclusions obtained from the simulations:

15



• The seismic activity is very intense during the first few hours or days after the occurrence

time of the primary earthquake, in the rectangular slice close to the edges of the fault;

• The immediate decay of this intense activity is followed by a period of time during which

the activity at larger distance (of the order of the linear dimensions of the fault) is nearly

constant. For longer time (several years) the total number of triggered events in the

external zone becomes comparable with that of the most internal one.

• the number of events triggered over a long time scale at distances larger than the fault

linear dimensions is significantly large;

• the seismic activity inside the fault drops to negligible values at the occurrence of the

primary earthquake and returns to normal values only after a time much longer than the

characteristic time (several tens of years in our simulations); for a long time range the

number of events inhibited inside the fault is comparable to that of the events triggered

outside: the net balance can be considered null; the seismicity rate changes in space and

time, but it does not have influence on the rate averaged over very large intervals of space

and time.

In light of the consequences derived from our model, both positive and negative perturba-

tions of the seismic activities resulting from the interactions among earthquakes would last for

a time of the order of decades. In this respect, it seems unrealistic to define and observe what

is commonly called ”background seismicity” of an area.

We can conclude that the model here analyzed, in spite of its very simple conception,

gives a physical justification both to the very popular phenomenon of short term earthquake

clustering (aftershocks and foreshocks in strict sense) and to that of the long term induction

and quiescence, also observed in various occasions.

We are confident that the refinement of the model and its validations with real catalogs

will bring to even more interesting consequences.

16



Acknowledgments

We are grateful to Massimo Cocco and Maria Elina Belardinelli for the stimulating discussions

and their criticism which led to a significantly better version of the paper. We thank Tom

Parsons for many useful suggestions to help make this paper clear.

17



Authors

R. Console,

Istituto Nazionale di Geofisica e Vulcanologia,

via di Vigna Murata, 605

00142, Rome, Italy

mailto: console@ingv.it

phone:+39 06 51860417

fax:+39 06 5041181

F. Catalli,

Istituto Nazionale di Geofisica e Vulcanologia,

via di Vigna Murata, 605

00142, Rome, Italy

mailto: catalli@ingv.it

phone:+39 06 51860571

18



Tables

Table 1: Source parameters used in numerical applications.

Parameter Value

Strike, dip and rake 0, 90, 0

Dimension of the fault 10 km×6 km

Spacing on the fault 0.1 km

Dimension of the grid 30 km×30 km

Spacing on the grid 0.5 km

Magnitude 6

Table 2: Constitutive parameters used in Dieterich’s relation.

Symbol Description

r reference seismicity rate

τ̇ shear stressing rate

τ̇r reference stressing rate

∆τ earthquake shear stress change

A fault constitutive parameter

σ normal stress

t time

ta characteristic time for seismicity to return to the steady state

19



Table 3: Values of the parameters used in the numerical applications of the model for induced

seismicity.

Parameter Value

r 4 events/(y · 1000km2)

τ̇ 5 KP a

τ̇r 5 KP a

A 0.008

σ 30 M P a

ta 48 y

20



Table 4: Relation between fault parameters and aftershock production. The value of ∆σ is

fixed at 4 M P a; the grid used in this computation has an area of 104 km2, the spacing on it is

0.5 km. The spacing on the fault is 0.05 km.

L · W [km2] M M0 [N m] Ntot

4 4.6 9.9 · 1015 13.4

25 5.4 1.5 · 1017 78.2

100 6.0 1.2 · 1018 263.2

225 6.4 4.2 · 1018 532.8

Table 5: Relation between fault parameters and aftershock production. The area of the fault

is fixed at the value of 100 km2, the spacing is of 0.05 km; the grid used in the computation

has an area of 17 × 17 km2, the spacing on it is of 0.5 km.

∆σ [M P a] M M0 [N m] Ntot

1 5.6 3.1 · 1017 51.8

2 5.4 6.2 · 1017 103.4

3 5.9 9.3 · 1017 155.2

4 6.0 1.2 · 1018 206.8

5 6.1 1.6 · 1018 258.6

Table 6: Relation between fault parameters and aftershock production. The value of M is fixed

at 6.0; the output grid is of 20 km×20 km, the spacing is 0.5 km. The spacing on the fault is

0.05 km.

L · W [km2] ∆σ [M P a] Ntot

4 510.7 overf low

25 32.7 597.6

100 4.1 223.2

225 1.2 107.8

21



Table 7: Results obtained for the best-fit of the sets of data reported in Figure 5 by the relation

(9). The symbol rms indicates the standard deviation.

Slice a [yp−1] c[y] p rms

(0 ÷ 0.5)km 3.24 ± 0.17 0.37 · 10−7 ± 0.2 · 10−6 1.02 ± 0.02 1.86

(0 ÷ 8.5)km 11.0 ± 0.76 0.23 · 10−7 ± 0.2 · 10−6 0.91 ± 0.032 9.16

(0.5 ÷ 8.5)km 83.7 ± 70.0 3.1 ± 1.96 1.44 ± 0.19 3.3

(0 ÷ 20)km 34.3 ± 8.0 0.13 · 10−1 ± 0.019 1.14 ± 0.077 9.22

(0 ÷ 100)km 36.8 ± 9.1 0.15 · 10−1 ± 0.023 1.12 ± 0.08 10.8

(20 ÷ 100)km 12.5 · 103 ± 10.9 · 103 61.0 ± 5.43 2.8 ± 0.96 · 10−3 0.45

22



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Figure captions

Figure (1): Conventions adopted for the reference system and for the parameters of the

orientation of a fault: the strike φ, dip δ and rake λ angles and the unit vectors n and l. The

x3 axis is positive toward the Nadir direction.

Figure (2): Shear stress, σ12, parallel to the slip direction for a strike-slip fault projected

on the fault plane (x1x3, x2 = 0.2 km).

Figure (3): Distribution of the triggered seismicity against time for different values of

induced shear stress. The values of the parameters used are: r = 2 events/y, ∆τ = 3 M P a,

Aσ = 0.24 and τ̇ = 5 KP a/y.

Figure (4): Distribution of the number of expected events in four different cases: (a) for

a positive value of earthquake shear stress equal to 5 MPa, (b) for a negative value of it equal

to -5 MPa, (c) the sum of (a) and (b) and (d) the integral of (c) over time. The values of r and

ta are fixed at 1.

Figure (5): Representation of the total number of induced events (on vertical axis) in six

different arbitrary slices (red, green and blue columns) around the principal fault after different

intervals of time (on horizontal axis). The distances of the limits of the slices are computed from

the perimeter of the source and the reference magnitude in the simulation is 6.0. Histogram (a)

represents the distribution nearest to the source at shorter intervals of time (the time scale is

purely qualitative). Histogram (b) represents the distribution farther from the fault at longer

intervals of time.

28



Figure (6): Spatial distribution of the density of induced events at t=0.01 year.

Figure (7): Spatial distribution of the density of induced events at t=1 year.

Figure (8): Spatial distribution of the density of induced events at t=100 year.

Figure (9): Comparison between the temporal distribution of the cumulative number of

induced events corresponding to synthetic data and the best fits obtained by the Omori law for

the closer slices from the source.

Figure (10): Comparison between the temporal distribution of the cumulative number of

induced events corresponding to synthetic data and the best fits obtained by the Omori law for

the farther slices from the source.

29



Figures

Figure 1:

Figure 2:

30



Figure 3:

Figure 4:

31



Figure 5:

32



Figure 6:

Figure 7:

33



Figure 8:

34



Figure 9:

Figure 10:

35