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1.
A first-order leveling survey across the northeast part of the Yellowstone caldera in September 1998 showed that the central
caldera floor near Le Hardy Rapids rose 24±5 mm relative to the caldera rim at Lake Butte since the previous survey in September
1995. Annual surveys along the same traverse from 1985 to 1995 tracked progressive subsidence near Le Hardy Rapids at an average
rate of –19±1 mm/year. Earlier, less frequent surveys measured net uplift in the same area during 1923–1976 (14±1 mm/year)
and 1976–1984 (22±1 mm/year). The resumption of uplift following a decade of subsidence was first detected by satellite synthetic
aperture radar interferometry, which revealed approximately 15 mm of uplift in the vicinity of Le Hardy Rapids from July 1995
to June 1997. Radar interferograms show that the center of subsidence shifted from the Sour Creek resurgent dome in the northeast
part of the caldera during August 1992 to June 1993 to the Mallard Lake resurgent dome in the southwest part during June 1993
to August 1995. Uplift began at the Sour Creek dome during August 1995 to September 1996 and spread to the Mallard Lake dome
by June 1997. The rapidity of these changes and the spatial pattern of surface deformation suggest that ground movements are
caused at least in part by accumulation and migration of fluids in two sill-like bodies at 5–10 km depth, near the interface
between Yellowstone's magmatic and deep hydrothermal systems.
Received: 30 November 1998 / Accepted: 16 April 1999 相似文献
2.
Water level records from gages on the shore of Yellowstone Lake and at its outlet are used to evaluate deformation year-by-year since 1923 on the southeastern flank of Yellowstone caldera. There is good agreement with deformation as measured by precise benchmark leveling surveys in 1923, 1976, 1983, 1984 and 1985. The water level record provides documentation of historical deformation of a large, dynamic, silicic caldera available by no other means, and it gives detail lacking from benchmark leveling prior to 1983 when annual surveys began. The data from southwest of Fishing Bridge suggest that this portion of the caldera has undergone relatively monotonic inflation since 1923 (0.4 μ radian/a up to the northeast) with a small, quasi-oscillatory variation superimposed. North of Fishing Bridge, the data suggest a higher rate with onset of quasi-oscillatory uplift ca. 1940 and a leveling-off since ca. 1965. Of particular importance are: the suggestion of episodic uplift and subsidence; the apparent lack of significant devation at the time of the M = 7.5 Hebgen Lake earthquake (1959); and the apparent subsidence of the intra-caldera area north of Fishing Bridge at the time of the M = 6.1. Norris earthquake (1975) with concurrent inflation of the flank of the caldera to the southwest. 相似文献
3.
Uplift of a broad area centered ~6 km west of the summit of South Sister volcano started in September 1997 (onset estimated
from model discussed in this paper) and was continuing when surveyed in August 2006. Surface displacements were measured whenever
possible since August 1992 with satellite radar interferometry (InSAR), annually since August 2001 with GPS and leveling surveys,
and with continuous GPS since May 2001. The average maximum displacement rate from InSAR decreased from 3–5 cm/yr during 1998–2001
to ~1.4 cm/yr during 2004–2006. The other datasets show a similar pattern, i.e., surface uplift and extension rates decreased
over time but deformation continued through August 2006. Our best-fit model to the deformation data is a vertical, prolate,
spheroidal point-pressure source located 4.9–5.4 km below the surface. The source inflation rate decreased exponentially during
2001–2006 with a 1/e decay time of 5.3 ± 1.1 years. The net increase in source volume from September 1997 to August 2006 was 36.5–41.9 x 106 m3. A swarm of ~300 small (M
max = 1.9) earthquakes occurred beneath the deforming area in March 2004; no other unusual seismicity has been noted. Similar
deformation episodes in the past probably would have gone unnoticed if, as we suspect, most are small intrusions that do not
culminate in eruptions. 相似文献
4.
William W. ChadwickJr Sigurjon Jónsson Dennis J. Geist Michael Poland Daniel J. Johnson Spencer Batt Karen S. Harpp Andres Ruiz 《Bulletin of Volcanology》2011,73(6):679-697
The May 2005 eruption of Fernandina volcano, Galápagos, occurred along circumferential fissures parallel to the caldera rim
and fed lava flows down the steep southwestern slope of the volcano for several weeks. This was the first circumferential
dike intrusion ever observed by both InSAR and GPS measurements and thus provides an opportunity to determine the subsurface
geometry of these enigmatic structures that are common on Galápagos volcanoes but are rare elsewhere. Pre- and post- eruption
ground deformation between 2002 and 2006 can be modeled by the inflation of two separate magma reservoirs beneath the caldera:
a shallow sill at ~1 km depth and a deeper point-source at ~5 km depth, and we infer that this system also existed at the
time of the 2005 eruption. The co-eruption deformation is dominated by uplift near the 2005 eruptive fissures, superimposed
on a broad subsidence centered on the caldera. Modeling of the co-eruption deformation was performed by including various
combinations of planar dislocations to simulate the 2005 circumferential dike intrusion. We found that a single planar dike
could not match both the InSAR and GPS data. Our best-fit model includes three planar dikes connected along hinge lines to
simulate a curved concave shell that is steeply dipping (~45–60°) toward the caldera at the surface and more gently dipping
(~12–14°) at depth where it connects to the horizontal sub-caldera sill. The shallow sill is underlain by the deep point source.
The geometry of this modeled magmatic system is consistent with the petrology of Fernandina lavas, which suggest that circumferential
eruptions tap the shallowest parts of the system, whereas radial eruptions are fed from deeper levels. The recent history
of eruptions at Fernandina is also consistent with the idea that circumferential and radial intrusions are sometimes in a
stress-feedback relationship and alternate in time with one another. 相似文献
5.
Following a period of net uplift at an average rate of 15±1 mm/year from 1923 to 1984, the east-central floor of Yellowstone Caldera stopped rising during 1984–1985 and then subsided 25±7 mm during 1985–1986 and an additional 35±7 mm during 1986–1987. The average horizontal strain rates in the northeast part of the caldera for the period from 1984 to 1987 were:
1 = 0.10 ± 0.09 strain/year oriented N33° E±9° and
2 = 0.20 ± 0.09 strain/year oriented N57° W±9° (extension reckoned positive). A best-fit elastic model of the 1985–1987 vertical and horizontal displacements in the eastern part of the caldera suggests deflation of a horizontal tabular body located 10±5 km beneath Le Hardys Rapids, i.e., within a deep hydrothermal system or within an underlying body of partly molten rhyolite. Two end-member models each explain most aspects of historical unrest at Yellowstone, including the recent reversal from uplift to subsidence. Both involve crystallization of an amount of rhyolitic magma that is compatible with the thermal energy requirements of Yellowstone's vigorous hydrothermal system. In the first model, injection of basalt near the base of the rhyolitic system is the primary cause of uplift. Higher in the magmatic system, rhyolite crystallizes and releases all of its magmatic volatiles into the shallow hydrothermal system. Uplift stops and subsidence starts whenever the supply rate of basalt is less than the subsidence rate produced by crystallization of rhyolite and associated fluid loss. In the second model, uplift is caused primarily by pressurization of the deep hydrothermal system by magmatic gas and brine that are released during crystallization of rhyolite and them trapped at lithostatic pressure beneath an impermeable self-sealed zone. Subsidence occurs during episodic hydrofracturing and injection of pore fluid from the deep lithostatic-pressure zone into a shallow hydrostatic-pressure zone. Heat input from basaltic intrusions is required to maintain Yellowstone's silicic magmatic system and shallow hydrothermal system over time scales longer than about 105 years, but for the historical time period crystallization of rhyolite can account for most aspects of unrest at Yellowstone, including seismicity, uplift, subsidence, and hydrothermal activity. 相似文献
6.
Johan Camitz Freysteinn Sigmundsson Gillian Foulger Cord-Hinrich Jahn Christof Völksen Pall Einarsson 《Bulletin of Volcanology》1995,57(2):136-145
GPS geodetic measurements were conducted around the Askja central volcano located at the divergent plate boundary in north Iceland in 1987, 1990, 1992 and 1993. The accuracy of the 1987 and 1990 measurements is in the range of 10 mm for horizontal components; the accuracy of the 1992 and 1993 measurements is about 4 mm in the horizontal plane. Regional deformation in the Askja region is dominated by extension. Points located outside a 30–45 km wide plate boundary deformation zone indicate a displacement of 2.4±0.5 cm/a in the direction N 99°E±12° of the Eurasian plate relative to the North American plate in the period 1987–1990. Within the plate boundary deformation zone extensional strain accumulates at a rate of 0.8 strain/a. Displacement of control points next to Askja (>7 km from the caldera center) in the periods 1990–1993 and 1992–1993 show deflation and contraction towards the caldera. These results are in accordance with the results obtained by other geodetic methods in the area, which indicate that the deflation at Askja occurs in response to a pressure decrease at about 2.8 km depth, located close to the center of the main Askja caldera. A Mogi point source was fixed at this location and the GPS data used to solve for the source strength. A central subsidence of 11±2.5 cm in the period 1990–1993 is indicated, and 5.5±1.5 cm in the period 1992–1993. The maximum tensional strain rate, according to the point source model, occurs at a horizontal distance of 2.5–6 km from the source, at the same location as the main caldera boundary. Discrepancies between the observed displacements and predicted displacements from the Mogi model near the Askja caldera can be attributed to the regional eastwest extension that occurs at Askja. 相似文献
7.
Erik Sturkell Freysteinn Sigmundsson Halldór Geirsson Halldór Ólafsson Theodór Theodórsson 《Journal of Volcanology and Geothermal Research》2008
The Krafla rifting episode, which occurred in North Iceland in 1975–1984, was followed by inflation of a shallow magma chamber until 1989. At that time, gradual subsidence began above the magma chamber and has continued to the present at a declining rate. Pressure decrease in a shallow magma chamber is not the only source of deformation at Krafla, as other deformation processes are driven by exploitation of two geothermal fields, together with plate spreading. In addition, deep-seated magma accumulation appears to take place, with its centre ∼ 10 km north of the Krafla caldera. The relative strength of these sources has varied with time. New results from a levelling survey and GPS measurements in 2005 allow an updated view on the deformation field. Deformation rates spanning 2000–2005 are the lowest recorded in the 30-year history of geodetic studies at the volcano. The inferred rate of 2000–2005 subsidence related to processes in the shallow magma chamber is less than 0.3 cm/yr whereas it was ∼ 5 cm/yr in 1989–1992. Currently, the highest rate of subsidence takes place in the Leirbotnar area, within the Krafla caldera, and appears to be a result of geothermal exploitation. 相似文献
8.
Joaquim J. Sousa Antonio M. Ruiz Ramon F. Hanssen Luisa Bastos Antonio J. Gil Jesús Galindo-Zaldívar Carlos Sanz de Galdeano 《Journal of Geodynamics》2010,49(3-4):181-189
Differential SAR interferometry (DInSAR) is a very effective technique for measuring crustal deformation. However, almost all interferograms include large areas where the signals decorrelate and no measurements are possible. Persistent scatterer interferometry (PS-InSAR) overcomes the decorrelation problem by identifying resolution elements whose echo is dominated by a single scatterer in a series of interferograms.Two time series of 29 ERS-1/2 and 22 ENVISAT ASAR acquisitions of the Granada basin, located in the central sector of the Betic Cordillera (southern Spain), covering the period from 1992 to 2005, were analyzed. Rough topography of the study area associated to its moderate activity geodynamic setting, including faults and folds in an uplifting relief by the oblique Eurasian–African plate convergence, poses a challenge for the application of interferometric techniques. The expected tectonic deformation rates are in the order of ~1 mm/yr, which are at the feasibility limit of current InSAR techniques.In order to evaluate whether, under these conditions, InSAR techniques can still be used to monitor deformations we have applied and compared two PS-InSAR approaches: DePSI, the PS-InSAR package developed at Delft University of Technology (TU Delft) and StaMPS (Stanford Method for Persistent Scatterers) developed at Stanford University. Ground motion processes have been identified for the first time in the study area, the most significant process being a subsidence bowl located at the village of Otura.The idea behind this comparative study is to analyze which of the two PS-InSAR approaches considered might be more appropriate for the study of specific areas/environments and to attempt to evaluate the potentialities and benefits that could be derived for the integration of those methodologies. 相似文献
9.
Inflation along Kilauea's Southwest Rift Zone in 2006 总被引:1,自引:0,他引:1
David Myer David Sandwell Benjamin Brooks James Foster Masanobu Shimada 《Journal of Volcanology and Geothermal Research》2008
We report on InSAR and GPS results showing the first crustal inflation along the southwest rift zone at Kilauea volcano in over 20 years. Two independent interferograms (May 2–August 2, 2006 and June 22–Nov 7, 2006) from the ALOS PALSAR instrument reveal domal uplift located southwest of the main caldera. The uplift is bounded on the northeast by the caldera and follows the southwest rift zone for about 12 km. It is approximately 8 km wide. We use data derived from permanent GPS stations to calibrate the InSAR displacement data and estimate uplift of 7.7 cm during the first interferogram and 8.9 cm during the second with line-of-sight volumes of 2.8 × 106 m3 and 3.0 × 106 m3 respectively. The earthquake record for the periods before, during, and after inflation shows that a swarm of shallow earthquakes (z < 5 km) signaled the beginning of the uplift and that elevated levels of shallow seismicity along the rift zones occurred throughout the uplift period. GPS data indicate that the inflation occurred steadily over nine months between mid-January and mid-October, 2006 making injection of a sill unlikely. We attribute the inflation to recharge of a shallow ductile area under the SWRZ. 相似文献
10.
Patricia A. Perlock Pablo J. González Kristy F. Tiampo Gema Rodríguez-Velasco Sergey Samsonov José Fernández 《Pure and Applied Geophysics》2008,165(8):1531-1554
Differential interferometry is a very powerful tool for detecting changes in the Earth’s crust where coherence conditions
are good, but is difficult to employ in some volcanic areas due to dense vegetation. We apply two differential InSAR methods
using the time series associated with the interferograms to perform a phase analysis on a data set for La Palma island (Canary
Islands) from the ERS-1 and ERS-2 European Space Agency (ESA) satellites for the time period 1992 to 2000. Both methods involve
choosing a master image from the database and creating a series of interferograms with respect to this image. The “Coherent
Pixel Time Series” (CPTS) technique chooses pixels with good average coherence, aligns the unwrapped interferograms with a
stable area and then performs an inversion to calculate the linear velocity to quantify the deformation. The Coherent Target
Modeling (CTM) method calculates the temporal coherence of each pixel to identify stable targets and then determines the best
velocity for each pixel by using a linear fit that maximizes the temporal coherence. Using these two methods we have been
able to detect deformation on La Palma Island that has been previously undetectable by conventional InSAR methods. There is
a roughly circular region on the Southern part of the island that is actively deforming at ~ −4 to −8 mm/yr. This region is
located near the Teneguia valcano, the host of the last known eruption on La Palma in 1971. A thorough investigation of the
possible sources for this deformation revealed that it was most likely created by a subsurface thermal source. 相似文献
11.
Daniel Dzurisin 《Bulletin of Volcanology》1999,61(1-2):83-91
Personnel from the U.S. Geological Survey's Cascades Volcano Observatory conducted first-order, class-II leveling surveys
near Lassen Peak, California, in 1991 and at Newberry Volcano, Oregon, in 1985, 1986, and 1994. Near Lassen Peak no significant
vertical displacements had occurred along either of two traverses, 33 and 44 km long, since second-order surveys in 1932 and
1934. At Newberry, however, the 1994 survey suggests that the volcano's summit area had risen as much as 97±22 mm with respect
to a third-order survey in 1931. The 1931 and 1994 surveys measured a 37-km-long, east–west traverse across the entire volcano.
The 1985 and 1986 surveys, on the other hand, measured only a 9-km-long traverse across the summit caldera with only one benchmark
in common with the 1931 survey. Comparison of the 1985, 1986, and 1994 surveys revealed no significant differential displacements
inside the caldera. A possible mechanism for uplift during 1931–1994 is injection of approximately 0.06 km3 of magma at a depth of approximately 10 km beneath the volcano's summit. The average magma supply rate of approximately 1×10–3 km3/year would be generally consistent with the volcano's growth rate averaged over its 600,000-year history (0.7–1.7×10–3 km3/year).
Received: 10 September 1998 / Accepted: 4 December 1998 相似文献
12.
Valerio Acocella 《Bulletin of Volcanology》2010,72(5):623-638
Understanding deformation of active calderas allows their dynamics to be defined and their hazard mitigated. The Campi Flegrei
resurgent caldera (Italy) is one of the most active and hazardous volcanoes in the world, characterized by post-collapse resurgence,
eruptions, ground deformation, and seismicity. An original structural analysis provides an overview of the main fracture zones.
NW-SE and NE-SW fractures (normal or transtensive faults and extensional fractures) predominate along the rim and within the
caldera, suggesting a regional control, both during and after the collapses. While the NE-SW fractures are ubiquitous in the
deposits of the last ∼37 ka, NW-SE fractures predominate in the last 4.5 ka, during resurgence. The most recently (<4.5 ka)
strained area lies in the caldera center (Solfatara area), where the faults, with an overall ∼ENE-WSW extension direction,
appear to be associated with the bending due to resurgence. Solfatara lies immediately to the east of the most uplifted part
of the caldera (Pozzuoli area), where domes form and culminate both on the long-term (resurgence, accompanied by volcanic
activity) and short-term deformation (1982–1984 bradyseism, accompanied by seismic and hydrothermal activity). Similar volcano-tectonic
behavior characterizes the short- and long-term uplifts, and only the intensity of the tectonic and volcanic activity varies,
being related to varying amounts of uplift. Seismicity and hydrothermal manifestations occur during the bradyseisms, with
moderate uplift, while surface faulting and eruptions occur during resurgence, with higher uplift. The features observed at
Campi Flegrei are found at other major calderas, suggesting consistent behavior of large magmatic systems. 相似文献
13.
方法,相干目标分析是利用时间序列多景影像获取地表稳定反射体——高相干点目标的新方法.实验区选择上海市主城区约100 km2 区域,InSAR的实验数据采用覆盖1992~2000年间的25景ERS-1/2的单视复影像.在无先验沉降场模型的情况下,实验结果显示该实验区的地面沉降场在时间范围上跨越8年,平均观测时间采样率约为4个月,垂直形变精度优于5 mm,满足我国对城市地面沉降形变观测的要求.研究结果表明该方法可以用于今后大时间/空间尺度上的高精度地表形变观测. 相似文献
14.
J. Ruch J. Anderssohn T.R. Walter M. Motagh 《Journal of Volcanology and Geothermal Research》2008,174(4):337-344
Collapsed calderas are the structural surface expression of the largest volcanic eruptions on Earth and may reach diameters of tens of kilometres while erupting volumes larger than 1000 km3. Remnants of collapse calderas can be found along the South American volcanic arc and are thought to be inactive. However, this study shows that systems of such dimension may become active in a relatively short period of time without attracting much attention. Using satellite-based InSAR data, a 45 km wide elongated area of ground deformation was observed in the Lazufre volcanic region (Chile), where no deformation was detected 10 years ago. The deformation signal shows an uplift of up to ~ 3 cm yr− 1 during 2003–2006, affecting an area of about 1100 km2, comparable in size to super-volcanoes such as Yellowstone or Long Valley. This deformation signal can be explained by an inflating magma body at about 10 km depth, expanding and propagating laterally at a velocity of up to 4 km per year. Although it is not clear whether this intrusion will lead to an eruption, its dimensions and the rapid deformation rate insinuate that a potentially large volcanic system is forming. 相似文献
15.
采用欧洲空间局ERS-2的星载干涉雷达数据,选取1997年11月8日MW7.6级玛尼地震作为研究对象,采用了差分干涉方法,在通过对覆盖同一地区的SAR数据进行差分干涉处理,得到了玛尼地震的视线向同震形变场。经研究发现:该地震形变场呈长轴近北东东向不规则椭圆形分布,地表破裂带长度约为130km,发震断层走向约为78°,断裂为左行走滑特征。断层以南为隆起区,在发震断层附近最大视线向隆起位移量为113.6cm,断层以北为沉降区,最大视线向沉降位移量为170.4cm。基于Okada模型实现了具有复杂结构的4段断层段参数的InSAR形变场数据模拟,获得断层的最大走滑为6m,估计出玛尼地震的标量地震矩M0为2.69×10^20Nm,计算得到的矩震级MW为7.6。证明了研究方法的正确性和研究结论的可靠性。 相似文献
16.
Leveling surveys in 1923, 1976, and each year from 1983 to 1993 have shown that the east-central part of the Yellowstone caldera, near the base of the Sour Creek resurgent dome, rose at an average rate of 14±1 mm/year from 1923 to 1976 and 22±1 mm/year from 1976 to 1984. In contrast, no detectable movement occurred in the same area from 1984 to 1985 (-2±5 mm/year), and from 1985 to 1993 the area subsided at an average rate of 19±1 mm/year. We conclude that uplift from 1923 to 1984 was caused by: (1) pressurization of the deep hydrothermal system by fluids released from a crystallizing body of rhyolite magma beneath the caldera, then trapped beneath a self-sealed zone near the base of the hydrothermal system; and (2) aseismic intrusions of magma into the lower part of the sub-caldera magma body. Subsidence since 1985 is attributed to: (1) depressurization and fluid loss from the deep hydrothermal system, and (2) sagging of the caldera floor in response to regional crustal extension. Future intrusions might trigger renewed eruptive activity at Yellowstone, but most intrusions at large silicic calderas seem to be accommodated without eruptions. Overpressurization of the deep hydrothermal system could conceivably result in a phreatic or phreatomagmatic eruption, but this hazard is mitigated by episodic rupturing of the self-sealed zone during shallow earthquake swarms. Historical ground movements, although rapid by most geologic standards, seem to be typical of inter-eruption periods at large, mature, silicic magma systems like Yellowstone. The greatest short-term hazards posed by continuing unrest in the Yellowstone region are: (1) moderate to large earthquakes (magnitude 5.5–7.5), with a recurrence interval of a few decdes; and (2) small hydrothermal explosions, most of which affect only a small area (<0.01 km2), with a recurrence interval of a few years. 相似文献
17.
Caldera eruptions are among the most hazardous of natural phenomena. Many calderas around the world are active and are characterised
by recurrent uplift and subsidence periods due to the dynamics of their magma reservoirs. These periods of unrest are, in
some cases, accompanied by eruptions. At Campi Flegrei caldera (CFc), which is an area characterised by very high volcanic
risk, the recurrence of this behaviour has stimulated the study of the rock rheology around the magma chamber, in order to
estimate the likelihood of an eruption. This study considers different scenarios of shallow crustal behaviour, taking into
account the earlier models of CFc ground deformation and caldera eruptions, and including recent geophysical investigations
of the area. A semi-quantitative evaluation of the different factors that lead to magma storage or to its eruption (such as
magma chamber size, wall-rock viscosity, temperature, and regional tectonic strain rate) is reported here for elastic and
viscoelastic conditions. Considering the large magmatic sources of the CFc ignimbrite eruptions (400–2,000 km3) and a wall-rock viscosity between 1018 and 1020 Pa s, the conditions for eruptive failure are difficult to attain. Smaller source dimensions (a few cubic kilometres) promote
the condition for fracture (eruption) rather than for the flow of wall rock. We also analyse the influence of the regional
extensional stress regime on magma storage and eruptions, and the thermal stress as a possible source of caldera uplift. The
present study also emphasises the difficulty of distinguishing eruption and non-eruption scenarios at CFc, since an unambiguous
model that accounts for the rock rheology, magma-source dimensions and locations and regional stress field influences is still
lacking. 相似文献
18.
利用InSAR技术,采用地震前后日本ALOS/ PALSAR数据,提取了2008年5月12日四川汶川地震7个条带的地表同震形变场.每个形变条带南北向500 km,东西向70 km,7个形变场覆盖了映秀镇、都江堰、茂县、北川、平武和青川.结果显示,此次地震地表破裂带在北川—映秀断裂带上.地表破裂带从汶川县映秀镇西南震中附近一直到青川县苏河北侧,全长约为230 km.发震断层西北盘为抬升盘,南东盘断层附近,仍然表现为隆起区,显示出以逆冲为主的断层性质.在汶川县映秀镇西侧震中区,最大相对卫星视线向形变量达260 cm,如果全部换算成垂直形变,则两个区域的垂直相对形变达3.3 m.从北川至平通一带,卫星视线向形变范围在120~180 cm的隆起带.其中,擂鼓镇隆起形变范围170~180 cm,换算成垂直形变约在2.2~2.3 m之间.在青川苏河北附近,有70~80 cm范围的隆起形变.在雅安、峨眉山一带,以及射洪至重庆北侧一带有大范围沉降区.在重庆及其南侧区域有幅度在20~30 cm小范围隆起.由青川向东至广元、宁强一带,有形变幅度在60~70 cm的隆起区.整个形变场影响范围较大,四川盆地出现了不同程度的地表形变. 相似文献
19.
New deformation data from the Askja volcano, Iceland, show that the volcano's caldera has been deflating continuously for over 20 years, and confirm that the rate of subsidence is slowing down. The decay in subsidence rate can be fitted with a function of the form e
−
t
/
τ
, where τ is 39 years. Reanalysis of GPS data from 1993–1998 show that these data can be fitted with a model calling for two Mogi point sources, one shallow, and another one much deeper (16.2 km depth). Pressure decrease occurs in both sources. The deeper source is responsible for observed horizontal contraction towards Askja at distances that cannot be explained by the shallower source. Plate spreading of 19 mm/year distributed evenly over about 100-km-wide zone is also favoured by the data. 相似文献
20.
2015年4月25日尼泊尔发生了MW7.8地震, 本文基于震前、 震后两景Sentinel-1A雷达影像, 采用D-InSAR两轨差分干涉法提取了此次地震的同震形变场。 结果显示, 同震形变场位于喜马拉雅造山带—主边界逆冲断裂(MBT)和主前锋逆冲断裂(MFT)附近, 形变场整体表现为自西北向往东南方向延伸近150 km的纺锤形包络状, 以大面积隆起抬升形变为主, 视线向最大隆升形变达1.18 m, 抬升区北侧存在一小沉陷区, 以InSAR观测值定位同震最大形变中心。 基于均匀介质弹性半空间模型(Okada模型)与InSAR观测数据反演了断层滑动分布。 反演结果表明该地震属于典型逆冲型地震, 发震断层为主喜马拉雅逆冲断裂(MHT), 同震破裂从主喜马拉雅逆冲断裂(MHT)向上沿着主前锋逆冲断裂(MFT)传递。 基于InSAR同震形变场局部形变细节, 结合震区地质背景、 断裂分布及断层运动特征, 获得了同震破裂拟出露地表迹线。 相似文献