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1.
We report results from a detailed study of seismicity in central Kamchatka for the period from 1960 to 1997 using a modified
traditional approach. The basic elements of this approach include (a) segmentation of the seismic region concerned (the Kronotskii
and Shipunskii geoblocks, the continental slope and offshore blocks), (b) studying the variation in the rate of M = 4.5–7.0 earthquakes and in the amount of seismic energy release over time, (c) studying the seismicity variations, (d)
separate estimates of earthquake recurrence for depths of 0–50 and 50–100 km. As a result, besides corroborating the fact
that a quiescence occurred before the December 5, 1997, M = 7.9 Kronotskii earthquake, we also found a relationship between the start of the quiescence and the position of the seismic
zone with respect to the rupture initiation. The earliest date of the quiescence (decreasing seismicity rate and seismic energy
release) was due to the M = 4.5–7.0 earthquakes at depths of 0–100 km in the Kronotskii geoblock (8–9 years prior to the earthquake). The intermediate
start of the quiescence was due to distant seismic zones of the Shipunskii geoblock and the circular zone using the RTL method, combining the Shipunskii and Kronotskii geoblocks (6 years). Based on the low magnitude seismicity (M≥2.6) at depths of 0–70 km in the southwestern part of the epicentral zone (50–100 km from the mainshock epicenter), the quiescence
was inferred to have occurred a little over 3 years (40 months) before the mainshock time and a little over 2 years (25 months)
in the immediate vicinity of the epicenter (0–50 km). These results enable a more reliable identification of other types of
geophysical precursors during seismic quiescences before disastrous earthquakes. 相似文献
2.
Numerous cases of precursory seismic quiescence have been reported in recent years. Some investigators have interpreted these observations as evidence that seismic quiescence is a somewhat reliable precursor to moderate or large earthquakes. However, because failures of the pattern to predict earthquakes may not, in general, be reported, and because numerous earthquakes are not preceded by quiescence, the validity and reliability of the quiescence precursor have not been established.We have analyzed the seismicity rate prior to, and in the source region of, 37 shallow earthquakes (M 5.3–7.0) in central California and Japan for patterns of rate fluctuation, especially precursory quiescence. Nonuniformity in rate for these pre-mainshock sequences is relatively high, and numerous intervals with significant (p<0.10) extrema in rate are observed in some of the sequences. In other sequences, however, the rate remains within normal limits up to the time of the mainshock. Overall, in terms of an observational basis for intermediate-term earthquake prediction, no evidence is found in the cases studied for a systematic, widespread or reliable pattern of quiescence prior to the mainshocks.In earthquake sequences comprising full seismic cycles for 5 sets of (M 3.7–5.1) repeat earthquakes on the San Andreas fault near Bear Valley, California, the seismicity rates are found to be uniform. A composite of the estimated rate fluctuations for the sequences, normalized to the length of the seismic cycle, reveals a weak pattern of a low rate in the first third of the cycle, and a high rate in the last few months. While these observations are qualitative, they may represent weak expressions of physical processes occurring in the source region over the seismic cycle.Re-examination of seismicity rate fluctuations in volumes along the creeping section of the San Andreas fault specified by Wyss and Burford (1985) qualitatively confirms the existence of low-rate intervals in volumes 361, 386, 382, 372 and 401. However, only the quiescence in volume 386 is found by the present study to be statistically significant. 相似文献
3.
Mitiyasu Ohnaka 《Pure and Applied Geophysics》1984,122(6):848-862
The Kanto earthquake (M=7.9) that occurred along the Sagami Trough in the Sagami Bay on 1 September 1923 was one of the most disastrous earthquakes in Japanese history. The Kanto area includes Metropolitan Tokyo and Yokohama which are densely populated, and hence it has been a matter of great concern, from the viewpoints of earthquake prediction and disaster prevention, whether or not the 1923 Kanto earthquake was preceded by precursory seismicity. A study using the most complete lists of earthquakes catalogued recently by Utsu and the Japan Meteorological Agency reveals that seismic activity in the Kanto area was appreciably higher before and after the Kanto earthquake, and that the Kanto earthquake was preceded by a sequence of anomalous seismic activity, quiescence, and foreshocks. Such higher activity before and after the Kanto earthquake is contrasted with low seismicity during the recent 30-year period. A model is proposed to explain the precursory seismic activity, subsequent quiescence, and foreshocks for the Kanto earthquake. In the model, the transition from precursory seismic activity to quiescence is ascribed to time-dependent fracture due to stress-aided corrosion. Foreshocks are related to an acceleration of premonitory slip shortly before the mainshock slip. 相似文献
4.
Robert O. Burford 《Pure and Applied Geophysics》1988,126(2-4):499-529
Records of shallow aseismic slip (fault creep) obtained along parts of the San Andreas and Calaveras faults in central California demonstrate that significant changes in creep rates often have been associated with local moderate earthquakes. An immediate postearthquake increase followed by gradual, long-term decay back to a previous background rate is generally the most obvious earthquake effect on fault creep. This phenomenon, identified as aseismic afterslip, usually is characterized by above-average creep rates for several months to a few years. In several cases, minor step-like movements, called coseismic slip events, have occurred at or near the times of mainshocks. One extreme case of coseismic slip, recorded at Cienega Winery on the San Andreas fault 17.5 km southeast of San Juan Bautista, consisted of 11 mm of sudden displacement coincident with earthquakes ofM
L
=5.3 andM
L
=5.2 that occurred 2.5 minutes apart on 9 April 1961. At least one of these shocks originated on the main fault beneath the winery. Creep activity subsequently stopped at the winery for 19 months, then gradually returned to a nearly steady rate slightly below the previous long-term average.The phenomena mentioned above can be explained in terms of simple models consisting of relatively weak material along shallow reaches of the fault responding to changes in load imposed by sudden slip within the underlying seismogenic zone. In addition to coseismic slip and afterslip phenomena, however, pre-earthquakeretardations in creep rates also have been observed. Onsets of significant, persistent decreases in creep rates have occurred at several sites 12 months or more before the times of moderate earthquakes. A 44-month retardation before the 1979M
L
=5.9 Coyote Lake earthquake on the Calaveras fault was recorded at the Shore Road creepmeter site 10 km northwest of Hollister. Creep retardation on the San Andreas fault near San Juan Bautista has been evident in records from one creepmeter site for the past 5 years. Retardations with durations of 21 and 19 months also occurred at Shore Road before the 1974 and 1984 earthquakes ofM
L
=5.2 andM
L
=6.2, respectively.Although creep retardation remains poorly understood, several possible explanations have been discussed previously. (1) Certain onsets of apparent creep retardation may be explained as abrupt terminations of afterslip generated from previous moderate-mainshock sequences. (2) Retardations may be related to significant decreases in the rate of seismic and/or aseismic slip occurring within or beneath the underlying seismogenic zone. Such decreases may be caused by changes in local conditions related to growth of asperities, strain hardening, or dilatancy, or perhaps by passage of stress-waves or other fluctuations in driving stresses. (3) Finally, creep rates may be lowered (or increased) by stresses imposed on the fault by seismic or aseismic slip on neighboring faults. In addition to causing creep-rate increases or retardations, such fault interactions occasionally may trigger earthquakes.Regardless of the actual mechanisms involved and the current lack of understanding of creep retardation, it appears that shallow fault creep is sensitive to local and regional effects that promote or accompany intermediate-term preparation stages leading to moderate earthquakes. A strategy for more complete monitoring of fault creep, wherever it is known to occur, therefore should be assigned a higher priority in our continuing efforts to test various hypotheses concerning the mechanical relations between seismic and aseismic slip. 相似文献
5.
V. A. Saltykov Yu. A. Kugaenko N. M. Kravchenko A. A. Konovalova 《Journal of Volcanology and Seismology》2013,7(1):58-75
This paper presents a set of seismicity parameters that are estimated at the Kamchatka Branch of the Geophysical Service, Russian Academy of Sciences based on the regional catalog data with the purpose of routine monitoring of the current seismic situation in the region. The focus is on the identification of changes in the seismic regime (seismic quiescences and seismicity increases) in earth volumes adjacent to the maturing rupture zone of a large earthquake. The techniques we use include estimation of the seismicity level for the region using the SOUS’09 scale; calculation of the variations in the slope of the recurrence relation, identification of statistically significant anomalies in the slope using the Z test, and calculation of the seismic activity A 10; monitoring the RTL parameter and variations in the area of seismogenic ruptures; using the Z test to detect areas of statistically significant decreases in the rate of seismicity; and identification of earthquake clusters. We furnish examples of such anomalies in these seismicity parameters prior to large earthquakes in Kamchatka. 相似文献
6.
本文基于“区域-时间-长度算法”(Region-Time-Length algorithm)回顾性检验了1976年以来发生在川滇地区的6个MS7.0以上和23个MS6.0~6.9地震前地震活动性变化。MS7.0以上强震前,5例检测到地震活动平静异常,仅1例检测到地震活动增强;MS6.0~6.9地震前,12例检测到平静,11例检测到地震活动增强。以上异常大部分出现于震前0.5~2.5a,持续0.5~2a。另外,发生在云南普洱地区的4个MS6.0以上地震震前都检测到平静异常;发生在北纬22.7°~31.0°N,99.6°~102.5°E范围内的17个地震,13例于震前检测到平静异常。以上研究对更好地认识川滇地区地震孕育过程和发震前兆提供了一些参考。 相似文献
7.
Two categories of earthquake precursors,physical and tectonic,and their roles in intermediate-term earthquake prediction 总被引:1,自引:0,他引:1
Katsuhiko Ishibashi 《Pure and Applied Geophysics》1988,126(2-4):687-700
I suggest that earthquake precursors can be divided into two major categories, physical and tectonic. I define physical precursor to be a direct or indirect indication of initiation or progression of an irreversible rupture-generating physical process within the preparation zone of a forthcoming earthquake. Tectonic precursor is defined as a manifestation of tectonic movement which takes place outside the preparation zone of an impending earthquake as a link in a chain of particular local tectonism in each individual area preceding the earthquake.Most intermediate-term, short-term and immediate precursors of various disciplines within the source regions of main shocks are considered physical ones. Some precursory crustal deformations around the source regions are, however, possibly tectonic precursors, because they may be caused by episodic plate motions or resultant block movements in the neighboring regions of the fault segments that will break. A possible example of this phenomena is the anomalous crustal uplift in the Izu Peninsula, Japan, before the 1978 Izu-Oshima earthquake ofM
s
6.8. Some precursory changes in seismicity patterns in wide areas surrounding source regions also seem to be tectonic precursors, because they were probably caused by the particular tectonic setting of each region. A typical example is a so-called doughnut pattern before the 1923 Kanto, Japan, earthquake ofM
s
8.2.Although most studies on earthquake precursors so far seem to regard implicitly all precursory phenomena observed as physical ones, the two categories should be distinguished carefully when statistical analysis or physical modeling is carried out based on reported precursory phenomena. In active plate boundary zones, where a practical strategy for earthquake prediction may well be different from that in intraplate regions, tectonic precursors can be powerful additional tools for intermediate-term earthquake prediction. 相似文献
8.
系统梳理了2000年以来山西地区6次MS≥4.5地震前地震活动异常,结果表明,地震空区/平静、地震条带、显著地震/震群、大同地震窗“开窗”活动等异常在地震发生前具有一定普遍性,且异常基本围绕在震中及附近地区分布,特别是在地震平静/空区、地震条带等异常发展后期出现的显著地震/震群活动,对未来地震发生的地点和时间具有较好的预测意义。异常持续时间与发震间隔统计表明:异常多出现在主震发生前6个月以内,显著地震/震群、大同地震窗“开窗”对未来主震的发生具有短临预测意义。此外,随着区域应力水平的不断增强,在特定敏感地区会发生成组极微震密集活动,监视跟踪这些有别于正常活动背景的极微震活动,对地震短临预测具有一定意义。 相似文献
9.
Geodetic deformation vs. seismic strain deduced by historical earthquakes across the Alborz Mountains 总被引:1,自引:0,他引:1
Mohammad Reza Zolfaghari 《Journal of Seismology》2009,13(4):647-663
Historical seismicity is used in order to map spatial distribution of seismic moment released by past earthquakes and to compare
strain rate deduced from seismicity to those measured by geodetic GPS survey. Spatial analyses are performed on the seismicity
of northern boundary of Central Iranian Block which coincides with the Alborz Mountains. This belt has been responsible for
several catastrophic earthquakes in the past. In this study, the records of historical and instrumental earthquakes in the
Alborz Mountains are used to calculate and plot geographical distribution of seismic moment released in time. A two-dimensional
distribution function is proposed and used here to spread seismic moment along causative tectonic features. Using accumulated
seismic moment, average slip rates across active faults are estimated for 32 sub-zones along the Alborz Mountains and western
Kopet Dag. Seismic moment released by historical and recent earthquakes on this belt accounts for slip rate of 3–5 mm/year
which is in good agreement with the geodetic vectors recently deduced from GPS survey in this region. The study also reveals
geographical variations of slip rates along some 900 km length of this zone based on seismic history. The results are compared
against finding from similar study in this region. Portions of Central and Eastern Alborz show lower seismic strain rate which
could imply aseismic motion or overdue earthquakes. Completeness of historical earthquake catalogue and its reliability with
regard to earthquake magnitudes, locations, and rupturing systems are among many plausible factors controlling the credibility
of such results. Therefore, any conclusions derived from these results remain as reliable as the data and assumptions used
for the analyses. 相似文献
10.
Western Macedonia, Northern Greece, was a seismically quiescent region for one or more centuries, and was regarded as a nearly aseismic, rigid block inside a broad zone of distributed continental deformation and faulting, and a region of minimum seismic risk. Consequently, the May 13, 1995 destructive earthquake (M = 6.6) which hit this assumed aseismic zone was a surprise for scientists, government and population.However, historical and archaeoseismic evidence, as well as coastal change data indicate that the assumed aseismic region of Western Macedonia has been affected in the last 2,000 years by at least seven, and possibly nine destructive earthquakes. One of these earthquakes occurred in circa 1700, and probably had the same epicentre with, but higher magnitude than the 1995 shock.The earthquake in circa 1700 is deduced from historical data and is modelled on the base of a swarm of church repairs which is explained as post-seismic recovery of the broader Kozani area: except for certain well known cases of towns or areas in which religious privileges were granted, large scale repairs or reconstruction of churches during the Ottoman period were possible only after Sultan's permissions, usually following earthquakes and other calamities.It can hence be concluded that some, at least, of the apparently aseismic regions inside broad zones of distributed seismicity are hit by stronger shocks, but with longer (200 years or more) recurrence intervals than their adjacent zones. Consequently, the seismic risk of the apparently aseismic regions is certainly not low, especially since relatively long periods of seismic quiescence lead to constructions vulnerable to earthquakes. 相似文献
11.
Yosihiko Ogata 《Pure and Applied Geophysics》2010,167(8-9):1115-1127
If aseismic slip occurs on a fault or its deeper extension, both seismicity and crustal deformation around the source would be affected. Anomalous phenomena of this kind are revealed from earthquake occurrence data and geodetic records during a period of 10 years leading up to the March 2005 M 7.0 earthquake west of Fukuoka that occurred off the northern coast of Kyushu, Japan. Seismicity rate anomalies (quiescence and activation) took place relative to the rates expected by the ETAS model in a number of seismic zones in and around the Kyushu District. The seismic zone of the relative quiescence and activation consistently corresponds to the zone of the negative and positive ΔCFS (Coulomb failure stress change), respectively, assuming the precursory aseismic slips on the M 7.0 source fault. In addition, we consider the time series of geodetic baseline distances between permanent GPS stations in the Kyushu District for the same period, which also supports the possible precursory slips rather than the known slow slips beneath the Bungo Straight, off the eastern coast of Kyushu. 相似文献
12.
为了了解2008年5月12日四川汶川MS8.0地震发生的地震活动背景,本文综合历史与现代地震资料,从南北地震带中段及其邻区的视野研究了汶川地震前1~2千年的强震活动性,以及震前20年的地震活动性背景.结果主要表明:(1)至少在2008年之前的1100~1700年中,龙门山断裂带未发生M≥7的地震,相对其南、北两侧的其他活动断裂带(或段)形成一个地震空区,2008年汶川MS8.0地震发生在该空区中;(2)17世纪以来,在由龙门山断裂带大部分地区、川北岷江-虎牙断裂带以及甘南文县-武都断裂带组成的巴颜喀拉块体东边界上共发生了12次M=6.5~8.0地震,显示出一个已持续了近400年、逐渐加速的应变能释放过程,2008年汶川MS8.0地震属于该过程中两次巨大地震之一;(3)汶川地震前20年,龙门山断裂带中、南段不存在背景地震活动的平静,反而显示出比曾经发生过1879年MS8地震的甘南文县-武都断裂带还略高的地震活动背景水平;(4)2008年汶川地震的强度远远超出龙门山断裂带的历史最大地震,说明仅基于数百年至一、两千年的历史地震记载,远不足以正确评估较低滑动速率的、大型活动断裂带的潜在地震危险性. 相似文献
13.
In this study, the seismic quiescence prior to hazardous earthquakes was analyzed along the Sumatra-Andaman subduction zone (SASZ). The seismicity data were screened statistically with mainshock earthquakes of M w?≥?4.4 reported during 1980–2015 being defined as the completeness database. In order to examine the possibility of using the seismic quiescence stage as a marker of subsequent earthquakes, the seismicity data reported prior to the eight major earthquakes along the SASZ were analyzed for changes in their seismicity rate using the statistical Z test. Iterative tests revealed that Z factors of N?=?50 events and T?=?2?years were optimal for detecting sudden rate changes such as quiescence and to map these spatially. The observed quiescence periods conformed to the subsequent major earthquake occurrences both spatially and temporally. Using suitable conditions obtained from successive retrospective tests, the seismicity rate changes were then mapped from the most up-to-date seismicity data available. This revealed three areas along the SASZ that might generate a major earthquake in the future: (i) Nicobar Islands (Z?=?6.7), (ii) the western offshore side of Sumatra Island (Z?=?7.1), and (iii) western Myanmar (Z?=?6.7). The performance of a stochastic test using a number of synthetic randomized catalogues indicated these levels of anomalous Z value showed the above anomaly is unlikely due to chance or random fluctuations of the earthquake. Thus, these three areas have a high possibility of generating a strong-to-major earthquake in the future. 相似文献
14.
15.
地震活动图像特征与强震危险区经验性预测依据的初步研究 总被引:1,自引:0,他引:1
在研究近期(10年)强震危险性判定和总结四川地区1972--2002年强震预测经验的基础上,清理了中国大陆1920--2002年47次浅源大震事件前地震活动图像特征(M≥4.7),提炼出10个方面12项经验性预测依据:主体活动区、多发时段、关联序列、大陆及地区地震异常图像、地区(带)-地段(震源区)地震增强图像(含信号震、诱发地震、地震条带)、相关地震、窗口地震、复发间隔、大陆及地区缺震、地段缺震与地段强震一缺震转折等。它们在47次震例中的综合出现率≥0.58(即依据比7/12以上)占42例;≥0.66(即8/12以上)占34例。因此,强震(M≥4.7)活动图像经验性预测依据可以作为预测有较大可能发生大地震危险区的依据之一。 相似文献
16.
Results are reported from a detailed study of central Kamchatka seismicity for the period 1962–1997 based on a modification
of the traditional approach. The approach involves (a) a detailed structure of the seismic region that recognizes the Kronotskii
and Shipunskii geoblocks and two further blocks, the continental slope, and the offshore portion, (b) a study of variations
in the rate of M = 3.0–7.2 earthquakes and the amount of seismic energy released at depths of 0–50 and 51–100 km, (c) a study
of seismicity variability, and (d) separate estimates of the recurrence of crust-mantle earthquakes (depths 0–50 km) and mantle
events (51–100 km). As a result, apart from corroborating the fact of a quiescence preceding the December 5, 1997 Kronotskii
earthquake (M 7.9), we also found that a relationship exists between its beginning and the position of the earthquake-generating
region relative to the mainshock epicenter. The quiescence dominates the seismic process during the pre-mainshock period and
is characterized by a decreased rate of earthquakes (the first feature) and a decreased amount of seismic energy release (the
second feature). Based on the first feature, we found that the quiescence started in 1987 throughout the entire depth range
(0–100 km) in both parts of the Kronotskii geoblock close to the rupture zone of the eponymous earthquake. As to the Shipunskii
geoblock, which is farther from the rupture zone, the quiescence began in the mantle of the inner area first (1988) and somewhat
later at depths of 0–50 km within the continental slope (1989). By the second feature, the quiescence began at shallower depths
in the inner area of the Kronotskii geoblock at the same time and later on (a year later) in the mantle (1988). Under the
continental slope of the trench in the Shipunskii geoblock the shallower quiescence also began in 1987, while it was 3 years
late in the inner zone (1990) and involved the earthquake-generating earth volume at depths of 0–100 km. These data are identical
with or sufficiently close to the estimate for the beginning of this quiescence using a circular area of radius 150 km that
combines the Kronotskii and Shipunskii geoblocks by the RTL method (1990). 相似文献
17.
The characteristics of spatio-temporal seismicity evolution before the Wenchuan earthquake are studied. The results mainly involve in the trend abnormal features and its relation to the Wenchuan earthquake. The western Chinese mainland and its adjacent area has been in the seismically active period since 2001, while the seismic activity shows the obvious quiescence of M≥?7.0, M≥?6.0 and M?≥5.0 earthquakes in Chinese mainland. A quiescence area with M?≥7.0 has been formed in the middle of the North-South seismic zone since 1988, and the Wenchuan earthquake occurred just within this area. There are a background seismicity gap of M?≥5.0 earthquakes and a seismogenic gap of ML?≥4.0 earthquakes in the area of Longmenshan fault zone and its vicinity prior to the Wenchuan earthquake. The seismic activity obviously strengthened and a doughnut-shape pattern of M?≥4.6 earthquakes is formed in the middle and southern part of the North-South seismic zone after the 2003 Dayao, Yunnan, earthquake. Sichuan and its vicinity in the middle of the doughnut-shape pattern show abnormal quiescence. At the same time, the seismicity of earthquake swarms is significant and shows heterogeneity in the temporal and spatial process. A swarm gap appears in the M4.6 seismically quiet area, and the Wenchuan earthquake occurred just on the margin of the gap. In addition, in the short term before the Wenchuan earthquake, the quiescence of earthquake with ML≥?4.0 appears in Qinghai-Tibet block and a seismic belt of ML?≥3.0 earthquakes, with NW striking and oblique with Longmenshan fault zone, is formed. 相似文献
18.
Before a strong earthquake, there is often a process of quiescence or 2absence2 of regional seismic activity, which is a phenomenon that has attracted the attention of many scholars in China and other countries (LU, et al, 1985; Wesson, 1973). In the past ten-odd years, some Chinese seismologists made, earlier or later, special studies on the quiescence anomaly of seismicity in some specified areas from different angles. Taking the converted annual frequency of M=5.0 earthquakes in North China region as a characteristic quantity, JIANG and FENG (1989) analyzed the quiescence anomaly of seismic activity by fuzzy recognition. 相似文献
19.
Mircea Radulian Cezar-Ioan Trifu Florin Octavian Cârbunar 《Pure and Applied Geophysics》1991,136(4):499-514
A numerical algorithm is proposed for the simulation of the earthquake process during a seismic cycle. The algorithm is based on a heterogeneous discrete model of the fault plane and assumes there are two kinds of seismicity: background crack-like earthquakes and asperity-like events. An active zone of the fault contains an asperity distribution with a characteristic elementary area. The background seismicity randomly develops shear stress-free surfaces which tend to surround the asperities as in a 2D percolation process. The model parameters are taken from observations on the Vrancea (Romania) intermediate depth seismic region. The results emphasize the significant role of the geometry in the mechanism of the seismic failure. The algorithm predicts the nonlinear behavior in the frequency-magnitude distribution, the decrease of theb-slope associated with the asperity-like events, the magnitude range of major earthquakes, and their recurrence times. 相似文献
20.
Evolving Towards a Critical Point: A Review of Accelerating Seismic Moment/Energy Release Prior to Large and Great Earthquakes 总被引:7,自引:0,他引:7
—There is growing evidence that some proportion of large and great earthquakes are preceded by a period of accelerating seismic activity of moderate-sized earthquakes. These moderate earthquakes occur during the years to decades prior to the occurrence of the large or great event and over a region larger than its rupture zone. The size of the region in which these moderate earthquakes occur scales with the size of the ensuing mainshock, at least in continental regions. A number of numerical simulation studies of faults and fault systems also exhibit similar behavior. The combined observational and simulation evidence suggests that the period of increased moment release in moderate earthquakes signals the establishment of long wavelength correlations in the regional stress field. The central hypothesis in the critical point model for regional seismicity is that it is only during these time periods that a region of the earth’s crust is truly in or near a "self-organized critical" (SOC) state, such that small earthquakes are capable of cascading into much larger events. The occurrence of a large or great earthquake appears to dissipate a sufficient proportion of the accumulated regional strain to destroy these long wavelength stress correlations and bring the region out of a SOC state. Continued tectonic strain accumulation and stress transfer during smaller earthquakes eventually re-establishes the long wavelength stress correlations that allow for the occurrence of larger events. These increases in activity occur over longer periods and larger regions than quiescence, which is usually observed within the rupture zone of a coming large event. The two phenomena appear to have different physical bases and are not incompatible with one another. 相似文献