陕西地区流动重力历史资料清理分析

介绍流动重力历史资料清理流程、方法及获得的规范化成果,对1998年泾阳M_S4.8、2009年高陵M_S4.4地震前后的重力场变化进行分析,得到结论:①泾阳地震前后重力场变化满足"震前重力持续增强一震后反向恢复"的特征;②泾阳地震的发生可能与附近断裂活动有关,同时受华北块体应力场的作用;③高陵地震前后重力变化与泾阳地震前后重力变化具有一定的相似性,且位于渭河断裂附近,两个地震均受到渭河断裂活动的影响。     

关中流动重力测网的中小地震映震能力分析

采用拟稳平差方法对1992—2011年陕西关中重力测网流动观测资料进行平差计算,获得各期高精度重力值,利用Kriging插值算法获得差分及累积重力场变化图像,结合1998年1月5日泾阳M_S4.8地震及2009年11月5日高陵M_S4.4地震,分析2次地震前后重力场及重力点值时序变化特征。结果表明:(1)2次地震前后都有较明显的重力异常变化,变化过程表现为正向―负向―正向重力变化,符合地震扩容模式;(2)2次地震的发生与渭河断裂及泾阳—渭南断裂构造活动有关,震中位置处于重力等值线零值线及拐弯处,但2次地震前重力累积变化不明显;(3)关中西部重力测点在2次地震前后重力值变化显著,关中东部重力点值变化不明显,震中附近的测点在泾阳地震前后变化明显,在高陵地震前后变化不明显。     

河西地区重力变化与2013年门源MS5.1地震研究

基于2010年5月—2013年10月的6期在河西地区流动重力测量资料获得的重力场时空变化结果,分析该区近期重力场变化及与2013年门源MS5.1地震的关系。结果表明：河西地区重力场变化空间分布显示在活动断裂附近重力变化较大,沿祁连山北缘断裂、昌马—门源断裂及庄浪河断裂形成与断裂带走向基本一致的重力变化高梯度带,反映了断裂构造活动引起的重力局部异常变化特征。2013年门源MS5.1地震发生在重力变化的高梯度带附近。     

雅江6.0级地震前后的重力变化异常特征

对川西地区2000～2001年雅江—康定间6．0级地震前后的重力观测资料进行了处理，绘制了重力场变化等值线图和三维曲面图，从动态的观点研究了雅江地震前后重力场的图像变化特征。结果表明：①重力变化与构造环境变化有关，地震前重力场有明显的异常变化。②雅江地震前后重力场空间分布图较好地反映了鲜水河断裂带及北西向的理塘断裂和北东的玉龙西断裂构造活动弓l起的重力变化。③地震发生在重力异常下降区及高梯度带附近。     

2014年山西平遥M_S4.1地震前后重力场变化特征分析

利用2012~2014年山西省绝对重力和流动重力观测资料,平差计算得到该时间段重力场变化值,分析区域重力场演化特征与2014年4月平遥MS4.1地震的关系。研究发现:(1)地震发生前研究区域出现了区域性的重力异常变化,在震中附近产生局部重力异常变化,形成了与活动断裂走向基本一致的重力变化高梯度带,这可能预示着与地震发生相关的构造运动或应力增强作用。(2)地震前后研究区重力场累积变化表现为应力场增强—持续增强—局部运动受阻超过临界值—能量突然释放,震后重力场变化恢复到平稳状态。     

泾阳4.8级地震前后重力变化探析

系统分析了泾阳Ms4．8地震前后陕西关中地区流动重力观测资料，探讨了重力场的时空变化及其映震特征。结果表明：①震前在震中区附近形成较显著地重力负异常区，且与沉降区基本吻合。②泾阳地震震中区既是重力变化梯度带，也是重力异常的正值区到负值区的过度带。③由于震源区应力作用方式是以水平为主的左旋走滑运动，震前局部重力异常不显著。     

川滇地区重力场动态变化及其强震危险含义

基于川滇地区2011—2014年的重力复测资料,系统分析了区域重力场时-空动态变化及其与2012年云南彝良MS5.7、2013年四川芦山MS7.0、2014年云南鲁甸MS6.5和四川康定MS6.3地震发生的关系.结合GPS、水准观测成果和区域地质构造动力环境,进一步研究了区域重力场变化的时空分布特征及其机理,讨论了近期区域重力场动态变化的强震危险含义.结果表明:1重力变化与川滇地区断裂构造活动存在密切空间联系,重力变化较好地反映了伴随活动断层的物质迁移和构造变形引起的地表重力变化效应.2重力资料对测区内2012年以来发生的4次MS5.7以上强震均有较好反映,地震前震中区及其附近观测到明显的区域性重力异常及重力变化高梯度带,可能是地震孕育过程中观测到的重力前兆信息.3区域重力场动态演化大体反映了青藏高原物质东流的动态效应,龙门山断裂带地壳受挤压隆起、面压缩率和重力上升变化的特征最为显著.4重力场的空间分布及其随时间变化与地壳垂直与水平运动及地质构造活动等观测结果有一定的对应关系,强震易发生在重力变化四象限分布中心地带或正、负异常区过渡的高梯度带上,研究区的一些重力异常部位仍存在中-长期大震危险背景.     

广西北流Ms5.2地震区域重力场变化

利用广西及邻区2016—2019年流动重力观测资料,系统分析区域重力场变化及其与广西北流M_S5.2地震的关系。结果表明:①北流M_S5.2地震前,震区附近重力异常变化与主干断裂关系密切,反映沿控震断裂在2016—2019年间发生了引起地表重力变化效应的地壳变形和构造活动;②差分重力图像表明北流M_S5.2地震前震中附近的重力变化是一个"局部重力异常→重力反向变化→重力变化平缓后发震"过程;③近期重力场累积动态图像表明玉林—岑溪—苍梧一带为重力变化剧烈区域,有利于应力的高度积累而孕育地震。     

福建重力场演变特征与仙游M_L 5.2级地震研究

对福建地区2008—2017年的流动重力复测资料进行系统整理和分析,从重力场时空变化角度分析了福建地区重力场演变特征,并重点研究了2013年仙游M_L 5.2级地震前区域重力场累积变化和震中附近测点重力点值时序变化,探讨了重力场变化与地震的关系。研究发现:福建地区重力场变化显著,且呈现逐渐增强态势;仙游地震发生前,沙县—南日岛断裂两侧重力正、负高值异常变化,震中附近测点重力值存在转折异常。     

2014年康定M_S6.3级地震前后的重力变化特征

利用四川地区2010年8月至2015年3月的流动重力观测数据作出重力场等值线变化图像,研究分析2014年康定MS6.3级地震前后的重力变化特征,结果表明:(1)三岔口地区长期保持区域性重力正值变化异常及重力变化高梯度带;(2)在康定MS6.3级地震前后三岔口地区的区域性重力正值变化异常及重力变化高梯度带变化并不是特别显著;(3)在康定MS6.3级地震前震区重力变化等值线出现四象限区域或者类似于四象限区域的分布特征;(4)康定MS6.3级地震发震位置处于0值线附近且0值线在此处发生明显的转折、畸变;(5)康定MS6.3级地震发生在重力减小后回调增加的过程中,震后重力继续回调增加。     

TEXTUAL RESEARCH OF 1568 M7 GAOLING EARTHQUAKE IN SHAANXI AND ANALYSIS OF ITS SEISMOGENIC STRUCTURE

Study of historical earthquake is one of the important methods to understand the seismic activities and analyze the seismogenic faults. On the May 25^th, 1568 AD, a destructive earthquake occurred to the northeast of the present-day city of Xi'an, Shaanxi Province. Because this earthquake happened shortly after the 1556 M8 earthquake and was regarded as an aftershock, it has received little attention in previous studies. Previous earthquake catalogue agreed in assigning a magnitude 6 3/4 to this earthquake but had different epicentral locations and seismic intensity, and the seismogenic structure remains ambiguous. Based on textual research of historical earthquake and field investigation, the Jingyang County, Gaoling County, and Xianning County, were the worst hit area by the earthquake, and the areas, including Yongle Town, Gaozhuang Town at southeastern Jingyang County to Gaoling County and its southeastern present-day Jijia and Zhangbu, should be the mesoseismal area of this earthquake. The epicenter intensity of this earthquake is Ⅸ⁺(9~10 degrees), and the magnitude is estimated to be 7. The isoseismal lines were drawn to exhibit the various intensities of the areas damaged during the event, with its major axis directed NWW. Intensities reached Ⅸ⁺ in the zone extending west-northwest parallel to the Weinan-Jingyang Fault. This fault, characterized by a normal fault that developed during the Cenozoic extensional history of the Weihe Basin, dipping to the north at an angle of 60°~80°, is one part of the southern boundary faults in Weihe graben. There are geomorphological and geological evidences of recent activity of the fault during (180±30)a BP to (1 600±30)a BP. At T₁-T₂ fluvial terraces on the north bank of Weihe River, the scarps were faulted during Ming Dynasty, and sandy soil liquefaction, dense structural tensional fissures and faulted strata are noted in stratigraphic profiles and trenches. Thus, we suggest that this fault can reliably be regarded as being active during Holocene, and re-name the earthquake as the Shaanxi Gaoling earthquake.     

1998年陕西泾阳MS4.8地震前高陵测点10m地温异常特征

研究分析了1998年1月5日陕西泾阳Ms4.8地震前高陵测点10m地温的变化特征。1997年高陵地温呈下降变化，12月15日温突升，该次地震前15天地温升高现象非常明显，震后恢复正常，西安市高压开关厂测点10m地温也从1997年12月中旬开始出现上升异常，1998年1月1日地温上升速度突然加大，可以认为，高陵测点观测到的10m地温异常是可信的。     

The stress change of the major activity faults in the Weihe Graben after the Wenchuan earthquake

The seismicity of small earthquakes in the Weihe Graben has changed after the Wenchuan earthquake. In detail,the seismicity around the Qishan-Mazhao fault in the western Weihe Graben decreased, while the seismicity in Gaoling and Jingyang Counties in the middle portion of the Weihe Graben and that in the area between Hancheng and Yuncheng Cities in eastern Weihe Graben increased. In this paper, the stress loading on the major activity faults in the Weihe Graben induced by the Wenchuan earthquake is discussed based on the Coulomb stress theory.The results show that the Wenchuan earthquake has exerted an unloading effect in the western Weihe Graben and a loading effect in the middle and eastern Weihe Graben. The spatially varied Coulomb stress is consistent with the seismicity distribution, indicating that the seismicity change is closely associated with the stress loading caused by the Wenchuan earthquake.     

1998年陕西泾阳M_S4.8地震前高陵测点10m地温异常特征

研究分析了 1 998年 1月 5日陕西泾阳MS4.8地震前高陵测点 1 0m地温的变化特征 .1 997年高陵地温呈下降变化 ,1 2月 1 5日地温突升 .该次地震前 1 5天地温升高现象非常明显 ,震后恢复正常 .西安市高压开关厂测点 1 0m地温也从 1 997年 1 2月中旬开始出现上升异常 ,1 998年 1月 1日地温上升速率突然加大 .可以认为 ,高陵测点观测到的 1 0m地温异常是可信的 .     

基于GRACE卫星和地表流动重力的汶川MS 8.0地震前重力时空变化

利用GRACE卫星重力场模型和地表流动重力观测资料,计算2008年汶川M_S 8.0地震发生前6年的重力变化,对卫星和流动重力段差结果与卫星重力反映的重力场动态变化特征进行研究,结果表明：①GRACE卫星重力段差受滤波半径影响显著,与地表流动重力观测结果相比,在重力变化数值上差异较大,在变化率上较为一致;②在汶川地震孕育阶段,川滇地区重力等值线呈“增大—减速增大—减小”的特征,震前2年形成近似垂直于龙门山断裂带的重力变化梯度带。     

渭河盆地及邻区重力异常小波多尺度分解与解释

基于EGM2008重力场模型计算获得了渭河盆地及邻区布格重力异常。采用小波多尺度分解方法对布格重力异常进行了4阶小波逼近和小波细节分解,同时基于平均径向对数功率谱方法定量化地计算出1~4阶小波细节和小波逼近所对应的场源平均埋深。结合区域地质和地震资料,对获得的重力场结果进行分析,得到如下结论:①鄂尔多斯地块、渭河盆地、秦岭造山带3个一级构造单元的布格重力异常之间存在明显差异;构造区内部重力异常也存在横向的显著差异。布格重力异常的走向、规模、分布特征与二级构造区及主要的断裂具有一定的对应关系。②渭河盆地及邻区布格重力异常1~4阶细节对应4~23 km不同深度的场源信息,鄂尔多斯地块南缘东、西部的地壳结构存在明显的差异;渭河盆地凹陷、凸起构造区边界清晰,断裂边界与重力异常边界具有较好的一致性;秦岭造山带重力异常连贯性不好,东、西部重力异常变化特征表现出明显的差异。③渭河盆地及邻区布格重力异常分布与莫霍面埋深具有非常明显的镜像关系。渭河盆地及邻区地震主要分布在六盘山—陇县—宝鸡断裂带、渭河断裂与渭南塬前断裂交汇处、韩城断裂与双泉—临猗断裂交汇处。渭河盆地及邻区重力异常主要由中上地壳剩余密度体所影响,这可能是该区地震以浅源地震为主的主要原因。     

汶川地震前后青藏高原东北缘重力场动态变化研究

通过对青藏高原东北缘重力观测资料进行整体平差计算, 系统分析了该区重力场在汶川8.0级地震前后重力场的时空动态演化特征。 研究结果表明, 汶川地震的发生使青藏高原深部物质向北东运移, 且部分通道受鄂尔多斯陆块的阻隔, 青藏高原东北缘区域重力场出现大空间尺度的趋势性显著重力变化; 汶川地震后, 甘、 宁、 陕交界的六盘山断裂带与西秦岭北缘断裂带以及之间地区重力场出现显著的非均匀变化, 该地区受汶川大地震的影响显著。     

基于GPS数据分析渭河盆地现今地壳形变特征

基于2001—2015年流动及连续GPS观测资料,借助多面函数拟合法建立渭河盆地水平速度场模型,并计算球面坐标下的应变特征参数。结合陕西地区地质构造背景,分析渭河盆地水平速度场及应变场分布特征。结果表明:(1)渭河盆地西部GPS速度场受青藏块体及鄂尔多斯块体共同作用明显,西部GPS速度场大于中东部,且GPS速度场有顺时针旋转的运动特征。(2)渭河盆地西部主应力场变化复杂,中部的西安地区主应变差异变化明显,与2009年11月5日高陵M_S4.4地震对应;渭河盆地西部出现最大剪应变及面应变高值区及差异变化高梯度带,在西安附近出现最大剪应变及面应变差异变化梯度带,高陵地震震中位于零值线附近。(3)2001—2010年的主应变、最大剪应变、面应变变化比2011—2015年显著,表明高陵地震发生后,应力场进行了释放调整,近期渭河盆地地震紧迫性相对较低。     

STUDY ON CHARACTERISTICS OF GRAVITY VARIATION BEFORE AND AFTER HUTUBI MS6.2 EARTHQUAKE

The Hutubi M_S6.2 earthquake of December 8, 2016 is a pure thrust event in the northern Tianshan thrust fold belt. The earthquake occurred between the Qigu Fault and the Junggar southern margin fault, which are both thrust faults. Based on mobile gravity measurements from 2013 to 2018 in the northern Tianshan, the gravity net adjustment was accomplished using Urumqi absolute gravity observation point as the datum, and the absolute gravity value of surface observation points were obtained. In order to eliminate the seasonal effect on gravity variation, the paper uses the observation data in May per annual as studying objects and obtains the temporal-spatial dynamic evolution images of gravity field differences in the northern Tianshan at different time scales as well as the time series of gravity variation of some points in the adjacent area of the epicenter. The characteristics of regional gravity variation before and after the Hutubi M_S6.2 earthquake on December 8, 2016 and their relations are analyzed systematically. The results show that: 1)The gravity variations in the study area are dramatic in generally, and the contours of gravity variation are consistent with the main faults basically. There was a four-quadrant distribution near the epicenter before the earthquake, and the Hutubi M_S6.2 earthquake occurred near the center of the four-quadrant distribution and at the turn of the gravity variation contour. The three years' cumulative gravity variation before the earthquake and the gravity variation after the earthquake are inversed, and the variation amplitudes are equivalent, suggesting that the M_S6.2 earthquake has released the stress and the energy accumulated before the earthquake. 2)This paper focuses on the analysis of gravity variation at the observation points on both sides of the Junggar southern margin fault near the epicenter. Regional gravity variation and gravity time series show that gravity variations at the same side of the Junggar southern margin fault are basically consistent, however, gravity variations at the different sides of the Junggar southern margin fault are different from each other obviously, indicating the difference of material migration laws in different structural regions. In addition, the strain energy accumulated in the epicenter is basically released after the earthquake, and the area nearby the epicenter tends to be stable. 3)The Hutubi M_S6.2 earthquake occurred near the center of the four-quadrant and at the turn of the high-gradient zone of gravity variation, reflecting the location of strong earthquake is related to the distribution of four-quadrant of regional gravity variation, the high-gradient zone of regional gravity variation and its turn. It has a unique advantage in determining the location of strong earthquake using gravity variation results. The regional spatial-temporal gravity variation before the earthquake is manifested as a systematic evolution process of “steady state→regional gravity anomaly→four-quadrant distribution→earthquake occurring in the reverse process”. Studying the temporal-spatial evolution characteristics of gravity field before and after Hutubi M_S6.2 earthquake has important practical significance for understanding the occurrence law of large earthquakes and capturing the precursory information of earthquakes.     

CHARACTERISTICS OF MULTI-SCALE GRAVITY FIELD VARIATION AND SEISMOGENIC MECHANISM ANALYSIS IN THE SOUTHEASTERN TIBETAN PLATEAU

As the most basic geophysical field, the earth gravity field has achieved wide attention, and its spatial anomaly characteristics and dynamic variation can provide important scientific basis for studying the internal structure and dynamics of the Earth. Based on the mobile gravity observation data of the southeastern Tibetan plateau from 2013 to 2016, the dynamic variation tendency and anomaly characteristics of the regional gravity field in different temporal resolutions are obtained before and after the Ludian and Jinggu earthquakes in the study area respectively. The method of wavelet multi-scale decomposition is used to analyze the relationships of gravity field variation with the earth movement, material density change, and strong earthquake preparation. The deep material variation, dynamic process and the mechanism of earthquake inoculation in the southeastern Tibetan plateau are further discussed. Results indicate that the gravity field variation in the source region before the Ludian and Jinggu earthquake respectively is characterized by obvious positive and negative anomalous transition zone and gradient zone that are consistent with the direction of fault tectonics, suggesting the strong crustal movement and mass migration during the earthquake incubation period. The result of wavelet multi-scale decomposition of the gravity field during the period from September 2013 to April 2014 shows that the gravity field variation at different depth and space scale in the crust and upper mantle of the southeastern Tibetan plateau is significantly correlated with seismic distribution and the location of active fault zone. This indicates that the earthquake inoculation in the study area is closely related to the fault movement and the distribution of material density in the crust and upper mantle, which may be affected by the complex deep dynamic process of the material migration in the crust and mantle. The characteristic that strong earthquakes always occur near positive and negative anomaly transition zones and gradient zones of gravity field change is preliminarily explained, based on the dynamic process of material migration in the crust and upper mantle of the southeastern Tibetan plateau. The research results of this paper have some reference value to the study on the earth movement and seismogenic mechanism.