Analysis of Deformation Characteristic and Uplift Mechanism in Longgang Volcanoes,Jilin

吉林龙岗火山区是第四纪活动火山,具有潜在喷发危险。通过GNSS和水准资料分析区域三维地壳运动,得出2011—2019年相对欧亚板块水平运动以东南向为主,速度＜10 mm/a。敦化-密山断裂以东受日本2011年“3·11地震”影响强烈,现以拉张运动为主;近年来水准资料揭示火山区垂直运动以隆升为主。2014—2019年的InSAR资料显示隆升集中在靖宇一带。结合MT剖面反演得到的深部电性结构,龙岗火山区西侧高阻体分布在深度18 km以上,金龙顶子火山下方最浅。中部为早期喷发形成的火山,下方高阻体分布在深度40 km以上,东侧抚松一带分布在深度约20 km以上,地壳范围内的高阻结构表明岩浆已固结。高阻结构层可分辨出断层两侧电阻的差异性。高阻体下方存在大规模低阻结构,推测为中下地壳岩浆系统。金龙顶子火山深度10 km以下的低阻结构可能为岩浆通道,并与中下地壳岩浆系统相连。东侧区域岩浆平均深度约30 km,相对较浅。龙岗火山区幔源物质的上涌及间断性的向上运移引起地壳隆升及地震活动。     

吉林省龙岗火山群现今活动性研究

吉林省龙岗火山区30多年构造地震活动一直很频繁,地震活动性明显强于附近的构造单元;通过对50年来的一等精密水准复测资料和该地区地震活动分析,发现龙岗火山群地区地壳整体上升,累计上升速度达40cm,明显大于其它地区地壳运动速率。这一现象可能预示龙岗火山的活动性有增强趋势。     

长白山火山区壳幔物性结构与深部物理场特征

长白山火山是一座具有潜在喷发危险的大型近代活动火山,因此通过对该火山活动的监测,加强对长白山天池火山岩浆系统的研究并了解天池火山的活动性质是很有意义的.除了开展长白山火山活动历史、火山地层学、火山岩岩石学、年代学以及火山地质等研究之外,我国从20世纪80年代开始在该火山区域进行了一系列的地球物理探测活动.为深入了解长白山火山区岩浆的分布与活动特征,本文对前人工作进行总结,得到了关于长白山火山活动的以下几个方面的认识:1)通过火山区地震活动性监测得到了火山区的岩浆活动状态;2)利用大地电磁测深对火山区地下是否存在可能再次活动的岩浆囊及其分布形态进行监测,为火山喷发的危险性预测和灾害评价提供依据;3)利用人工源深地震测深对长白山天池及其邻域的结晶基底及地壳精细结构进行讨论;4)利用天然地震对火山区地壳、上地幔结构进行深入研究,分析了与火山区有关的深层动力学因素;5)对国外火山区重力监测实例的调研表明,重力监测对了解岩浆活动状态是十分有效的手段.多种地球物理方法的综合应用,获得了长白山火山地区地壳至地幔转换带的详细资料.     

长白山天池火山区及邻近地区壳幔结构探测研究

对长白-敦化深地震测深剖面资料利用二维射线追踪程序包进行走时拟合及地震图计算,得到了长白山天池火山区及邻近地区地壳上地幔速度结构和深部构造. 结果表明,以C2界面为标志,研究区地壳可分为上部地壳和下部地壳. 上部地壳厚1-23km,P波速度为6.00-6.25km/s;下部地壳厚12-17km,它是由一个较均匀的速度层和一个厚6-km的壳幔过渡层构成. 地壳厚度由敦化一带31-33km向东南逐渐增厚,至天池火山区最深达3km. 在天池火山区地壳存在低速体,其速度较周围介质低约为0.15km/s. 利用地震剖面探测、地震CT和大地电磁测深等结果显示,在天池火山区地壳内存在低速、低密度及低阻异常体,该异常体可能表明壳内岩浆囊的存在.     

腾冲地区地壳速度结构的有限差分成像

利用流动台网和固定台站的地震观测数据,采用有限差分层析成像方法反演了腾冲及邻近地区的地壳P波速度结构,分析了腾冲火山区的岩浆活动和龙陵七级地震的深部构造成因.研究结果表明,腾冲火山区的地壳结构具有明显的非均匀性,浅表层偏低的速度主要为盆地内部的松散沉积层、新生代火山堆积及断裂附近的流体裂隙和热泉活动所致;5～15 km之间的高速体可能代表了早期火山通道内冷却固结的岩浆侵入体或难挥发的超铁镁质残留体;地壳深部的低速体则反映了熔融或半熔融的岩浆体,推断火山区下方的岩浆活动与龙陵七级地震震源区地壳深部的岩浆侵入来自同一源区--现今壳内岩浆活动的主要区域.龙陵震源区的地壳速度结构横向变化较大,怒江断裂东侧和龙陵断裂西侧为高速特征,介质应变强度较大,为应力积累的主要载体;两断裂之间的低速区向下延伸至下地壳,可能与地壳深部的岩浆侵入有关;龙陵断裂和怒江断裂明显控制了这一区域的岩浆活动,七级地震正是发生在断裂下方的速度边界附近.地壳介质强度的横向变化导致了震源区应力积累的不均一性,深部岩浆的聚集和动力作用是龙陵地区发生强震的主要原因.     

第四纪火山活动典型地区地震活动特征研究

火山活动区内的地震活动有其特殊性与复杂性。针对我国第四纪典型火山区的火山活动及地震活动特征进行了分析总结,认为第四纪火山区内的地震活动的最大震级不高于6.5级,且火山区内的地震活动强度相对其周边地区来说要弱,这表明火山活动区不利于积累大的弹性应变能,其地壳内岩浆房的存在,可能限制了地壳岩石的孕震能力,从而使火山区无强震发生,火山区内活动断裂的活动主要表现在作为深部岩浆的上涌通道,故对火山区的未来地震危险性评价方面要有所区别。同时由于中强地震多发生在火山区的外部边缘,因此我们要特别注意火山外缘地区的中强地震活动,特别是加强对位于火山外缘地区的活动断裂的研究。     

龙岗火山区尾波Q值的初步研究

基于sato单次散射模型,利用2007年5月至2010年2月龙岗火山测震台网记录到的发生在火山区及邻近地区内的41次Mt.≥1.6地震的波形资料,计算了龙岗火山区的尾波Q值,得出尾波Q值与频率的关系为Q(f)=(42.65±7.53)f(0.845 9+0.164 2),具有以低Q值高η值为特征的火山构造活跃地区的尾波...     

腾冲火山区的地震层析成像及其构造意义

利用滇西南临时台网和固定台站的地震数据反演了腾冲及邻近地区的P波速度结构,着重分析了腾冲火山区和龙陵7级地震震源区的地壳结构特点.研究结果表明,腾冲火山区下方10～20 km深度范围存在明显的低速区,其横向尺度大约在20～30 km之间;推测这一低速区代表了仍处于活动状态的壳内岩浆源,热流通道有可能通过腾冲断裂延伸至地...     

海口地区火山活动初步研究

海口地区的马鞍岭-雷虎岭火山群是中国为数不多的几个休眠火山群之一。通过对区域火山活动期次划分、深部岩浆囊探测以及对火山类型、规模、物质组成和溶岩覆盖面积的分析,总结了海口地区火山活动的时、空、强特征。结合对火山区地震、地磁、体应变和地热等观测资料的分析,对火山区深部岩浆活动的状态进行了初步评估。研究认为海口全新世火山区最后一次火山喷发距今约4 000a左右,其现今火山活动已趋于平静,未来的火山活动可能向1605年琼州7.5级大地震震中区迁移     

火山区台站观测的地震波分析与应用

以长白山天池台记录的地震Ｐ、Ｓ波及腾冲台记录的地脉动资料为基础，分析研究了火山区台站观测的地震波在微震监测与分析、火山地震类型判别、火山区介质非均匀性与各向异性分析以及地震预报与火山喷发监测在预报中的应用．     

火山岩地区断层活动时代鉴定中的问题及其讨论

通过野外地质、地貌调查,对新生代玄武岩普遍发育的吉林省靖宇县龙岗火山群地区的断层活动性进行了研究,结合断层物质ESR测年分析结果以及本地区第四纪火山活动的特点,发现ESR测年数据与野外实际观察到的地质现象比较相对偏新。文中讨论了产生这一现象的两个可能原因:1)研究地区大规模的第四纪岩浆喷发活动作为一种重要的热事件,对于先存的断层物质中的ESR测年信号具有"退火"和零化作用;2)化学风化作用、地下水的淋滤作用、次生物质的混入和富硅热液作用而导致的次生石英颗粒的增长,都可能会导致断层带物质ESR测年剂量的增加,从而引起测年结果偏新。因此,研究区ESR测年结果反映出的并非是断层最后一次的活动年代,而可能是断层活动的上限年龄。尽管与实际的断层活动年龄有较大的差距,但对于大型工程场地的地震安全性评价,尤其是对于能动断层的鉴定,这种"上限年龄"仍然具有十分重要的应用价值     

腾冲火山区水平形变初探

介绍了采用精密大地测量的方法,对腾冲火山区域的水平形变情况进行了探索。通过两期相距３８年的实测数据,对火山“休眠期”中岩浆活动与地壳局部变形的相关性进行研究,并提供了部分计算结果。作者认为,采用精密大地测量的方法对火山区域地壳变形进行研究是可行的;火山区域水平形变与构造形变的区别是存在的;腾冲火山区内近几十年内岩浆的动也是明显的,但目前总体为间歇性收缩期;从水平形变测量的结果来看,显示了南面活跃的迹象;且认为可能是岩浆囊的存在才会引起此大范围的地壳活动。     

利用垂直形变资料分析龙岗火山的活动性

首先分析了龙岗火山区及其附近20多年来5条水准路线所反映的垂直形变背景场情况,发现相对于长春基准点,长白山区东部和北部地区主要表现为大面积下沉运动,而龙岗火山区则表现为相对上升运动;然后分析了龙岗火山区主要隆起区垂直形变场变化以及剪切和张裂变形率变化,所得结果均反映了长抚线发生了较明显的活动;最后运用改进的Mogi模型,采用L曲线法反演了主要隆起区可能的压力源参数.结果表明,龙岗火山区岩浆的位置在42.1°N,126.5°E附近,与深地震测深研究结果近似.相对于长白山天池火山,压力源等效半径变化较大,达到183 m左右,源的深度在30 km左右,相对较深.     

Seismicity and crustal deformation preceding the January 1996 eruptions at Karymsky Volcanic Center,Kamchatka

Two explosive eruptions occurred on 2 January 1996 at Karymsky Volcanic Center (KVC) in Kamchatka, Russia: the first, dacitic, from the central vent of Karymsky volcano, and the second, several hours later, from Karymskoye lake in the caldera of Akademia Nauk volcano. The main significance of the 1996 volcanic events in KVC was the phreatomagmatic eruption in Karymskoye lake, which was the first eruption in this lake in historical time, and was a basaltic eruption at the acidic volcanic center. The volcanic events were associated with the 1 January Ms 6.7 (Mw 7.1) earthquake that occurred at a distance of about 9–17 km southeast from the volcanoes just before the eruptions. We study the long-term (1972–1995) and short-term (1–2 January 1996) characteristics of crustal deformations and seismicity before the double eruptive event in KVC. The 1972–1995 crustal deformation was homogeneous and characterized by a gradual extension with a steady velocity. The seismic activity in 1972–1995 developed at the depth interval from 0 to 20 km below the Akademia Nauk volcano and spread to the southeast along a regional fault. The seismic activity in January 1996 began with a short sequence of very shallow microearthquakes (M ~0) beneath Karymsky volcano. Then seismic events sharply increased in magnitude (up to mb 4.9) and moved along the regional fault to the southeast, culminating in the Ms 6.7 earthquake. Its aftershocks were located to the southeast and northwest from the main shock, filling the space between the two active volcanoes and the ancient basaltic volcano of Zhupanovsky Vostryaki. The eruption in Karymskoye lake began during the aftershock sequence. We consider that the Ms 6.7 earthquake opened the passageway for basic magma located below Zhupanovsky Vostryaki volcano that fed the eruption in Karymskoye lake.     

Geophysical characteristics of dacite volcanism — the 1977–1978 eruption of Usu volcano

The 1977–1978 eruption of Usu volcano is discussed from the geophysical standpoint as a classic example of dacite volcanism. The activities of dacitic volcanoes are characterized by persistent earthquake swarms and remarkable crustal deformations due to the high viscosity of the magmas; the former include shocks felt near the volcanoes and the latter accompany formation of lava domes or cryptodomes.The hypocenters of the earthquakes occurring beneath Usu volcano have been located precisely. Their distribution defines an earthquake-free zone which underlies the area of doming within the summit crater. This zone is regarded as occupied by viscous magma. The domings within the summit crater forming the cryptodomes have amounted to about 160 m. In addition to uplift they showed thrusting towards the northeast. As a result, the northeastern foot of the volcano has contracted by about 150 m. The relation between crustal deformation and earthquake occurrence is examined, and it is found that the abrupt domings are accompanied by the larger earthquakes (M = 3–4.3). Both the seismic activity and the ground deformation are shown to have a unique and common energy source.The energy of activities of Usu volcano consists of the explosive type, the deformation type and the seismic type; the second and the third are in parallel with each other in discharges, and both energies are complementary to the explosive energy. The explosive energy and the seismic energy have been calculated for an explosion sequence, and it is concluded that the deformation energy is about 10 times greater than the seismic energy. The discharge rate of the seismic energy and the upheaval rates of the cryptodomes have continued to decrease since the outburst of the eruption, except for a small increase at the end of January 1978. Eruptions are governed not only by the supply of the energies but also by the depth of the magma, which has gradually approached the surface. The last eruption occurred in October 1978; however, the crustal deformations and the earthquake swarms are still proceeding as of January 1980, albeit at a lower rate of activity.     

Modeling ground deformations of Panarea volcano hydrothermal/geothermal system (Aeolian Islands, Italy) from GPS data

Panarea volcano (Aeolian Islands, Italy) was considered extinct until November 3, 2002, when a submarine gas eruption began in the area of the islets of Lisca Bianca, Bottaro, Lisca Nera, Dattilo, and Panarelli, about 2.5 km east of Panarea Island. The gas eruption decreased to a state of low degassing by July 2003. Before 2002, the activity of Panarea volcano was characterized by mild degassing of hydrothermal fluid. The compositions of the 2002 gases and their isotopic signatures suggested that the emissions originated from a hydrothermal/geothermal reservoir fed by magmatic fluids. We investigate crustal deformation of Panarea volcano using the global positioning system (GPS) velocity field obtained by the combination of continuous and episodic site observations of the Panarea GPS network in the time span 1995–2007. We present a combined model of Okada sources, which explains the GPS results acquired in the area from December 2002. The kinematics of Panarea volcano show two distinct active crustal domains characterized by different styles of horizontal deformation, supported also by volcanological and structural evidence. Subsidence on order of several millimeters/year is affecting the entire Panarea volcano, and a shortening of 10⁻⁶ year⁻¹ has been estimated in the Islets area. Our model reveals that the degassing intensity and distribution are strongly influenced by geophysical-geochemical changes within the hydrothermal/geothermal system. These variations may be triggered by changes in the regional stress field as suggested by the geophysical and volcanological events which occurred in 2002 in the Southern Tyrrhenian area.     

Geodetic methods for detecting volcanic unrest: a theoretical approach

In this paper we study the application of different geodetic techniques to volcanic activity monitoring, using theoretical analysis. This methodology is very useful for obtaining an idea of the most appropriate (and efficient) monitoring method, mainly when there are no records of geodetic changes previous to volcanic activity. The analysis takes into account the crustal structure of the area, its geology, and its known volcanic activity to estimate the deformation and gravity changes that might precede eruptions. The deformation model used includes the existing gravity field and vertical changes in the crustal properties. Both factors can have a considerable effect on computed deformation and gravity changes. Topography should be considered when there is a steep slope (greater than 10°). The case study of Teide stratovolcano (Tenerife, Canary Islands), for which no deformation or gravity changes are available, is used as a test. To avoid considering topography, we worked at the lowest level of Las Cañadas and examined a smaller area than the whole caldera or island. Therefore, the results are only a first approach to the most adequate geodetic monitoring system. The methodology can also be applied to active areas where volcanic risk is not associated with a stratovolcano but instead with monogenetic scattered centers, especially when sites must be chosen in terms of detection efficiency or existing facilities. The Canary Islands provide a good example of this type of active volcanic areas, and we apply our model to the island of Lanzarote to evaluate the efficiency of the monitoring system installed at the existing geodynamic station. On this island topography is not important. The results of our study show clearly that the most appropriate geodetic volcano monitoring system is not the same for all different volcanic zones and types, and the particular properties of each volcano/zone must be taken into account when designing each system.     

腾冲火山及其周围地区的地壳Q值特征

本利用腾冲火山活动区及周围地区的地方震尾波资料。根据尾波散射理论,研究了火山地区及周围地区的地壳Ｑ值。结果表明,火山地区的地壳Ｑ值最低。为９５,近邻区的龙陵－－保山地区的１７０－１５０之间。,周围地区最高达２９５左右。是火山地区的１．８－３．０倍左右。地壳Ｑ值的空间２明显表现出腾冲火山活动区为低Ｑ值区,而周围地区为高Ｑ值地区,这种地壳Ｑ值的空间２差异也许反映了火山地区内部介质状态与周围地区构造地     

基于区域水准和跨断层资料分析云南地区地壳形变

为了获取云南地区现今地壳形变和断层活动特征,收集了云南地区1992—2016年的2期精密水准观测资料,采用基于GNSS连续站垂直形变资料约束的平差方法,对区域整体地壳垂直形变特征进行了分析,结果显示滇西北区域地壳整体表现为隆升,垂向速率为2—3mm/a,滇南区域显示地壳沉降速率为-1—-2mm/a,并在下关—永胜和思茅—景谷一带存在地壳形变高梯度带。收集了该地区30多年的跨断层场地观测资料,计算了所跨断层的三维活动量,得出了断层现今活动状态和异常特征,认为滇西北和滇中南地区的场地多数表现出异常活动的现象,其中楚雄、剑川和永胜的监测断层现今表现出与地质背景相反的走滑和拉张特征,峨山、建水和通海场地所处断层在张压性质上与地质背景相反。结合区域水准和跨断层观测分析结果,从“面”和“线”上得出滇西北和滇中南地区存在地壳形变和断层活动异常,构造应力积累较高的结果,加之缺震背景显著,认为应关注该区域中强地震的危险性。