Morphological responses ofLimnocythere inopinata (Ostracoda) to hydrochemical environment factors

Living ostracod and hydrochemical samples were collected synchronously from more than 50 lakes and small water body in the eastern edge area of the Tibetan Plateau, Northern Tibetan, Southern Tibet and mid-Tibet. The comparison of the adult body length ofLimnocythere inopinata and hydrochemical parameters of their habitats shows that a quantitative relationship exists between the adult body length and salinity expressed as conductivity. An empirical formula to reconstruct paleosalinity is suggested first and applied to salinity reconstruction of CE-2 core from Cuoe Lake, Tibet. The method is verified by comparing its outcome with results of other environment reconstruction methods.

     

Diatom assemblages and quantitative reconstruction for paleosalinity from a sediment core of Chencuo Lake,southern Tibet

Changing salinity in lakes and especially in closed lakes depends mainly on the balance between precipitation, runoff and evaporation in arid and semi-arid areas, hence influencing lake levels di-rectly[1-4]. Past salinity has been recovered by a vari-ety of environmental indicators from lake sediments such as diatoms, chironomids, ostracoda, isotopes of ostracoda shells, geochemistry, and isotopes of authi-cabonates[3,5—10]. Recently, with extensive data-base study on diatom-salinity transfe…     

Seismic anisotropy beneath Tibet: evidence for eastward extrusion of the Tibetan lithosphere?

Strong seismic anisotropy beneath Tibet has recently been reported from the study of SKS shear wave splitting. The fast split waves are generally polarized in an easterly direction, close to the present day direction of motion of the Tibetan crust relative to stable Eurasia, as deduced from Holocene slip rates on the major active faults in and around Tibet. This correlation may be taken to suggest that the whole Tibetan lithosphere is being extruded in front of indenting India and that the anisotropic layer is the deforming asthenosphere, that accommodates the motion of the Tibetan lithosphere relative to the fixed mantle at depth. Uncertainties about this motion are at present too large to bring unambiguous support to that view. Assuming that this view is correct however, a simple forward model is used to compute theoretical delay times as a function of the thickness of the anisotropic layer. The observed delay times would require a 50–100 km thick anisotropic layer beneath south-central Tibet and an over 200 km thick layer beneath north-central Tibet, where particularly hot asthenosphere has been inferred. This study suggests that the asthenospheric anisotropy due to present absolute block motion might be dominant under actively deforming continents.     

The present-day state of spring runoff in the territory of Ural Hydrogeological Massif (The Middle Urals)

Data on the spring runoff of the mountain-folded part of the Middle Urals are generalized to analyze the transformation of its macrocomponent composition from 1954 to 2005. Regional stochastic models for ten hydrochemical indices are presented. The current regional hydrochemical background is substantiated. The salinity and total hardness of the spring water are shown to increase on the regional scale.     

Geodynamical basis for crustal deformation under the Tibetan Plateau

This paper uses plate tectonics and satellite-derived gravity data to further discussion of crustal deformation under the Tibetan Plateau. The first of our three contributions is a spherical harmonic analysis of the global plate boundary system. A distribution of 470 Dirac delta functions is applied to describe the generating forces according to the rates of crustal creation and destruction on the plate boundaries. Analysis of the extensional and compressional forces in the spreading and subducting zones shows that the present global plate motion causes compressional stresses in the N-S direction under the Tibetan Plateau. The second contribution is the calculation of the crustal stresses in Tibet as inferred from satellite gravity data. By applying solutions to the problem of the spherical shells, the satellite-determined stresses indicate that the up-welling mantle material under Tibet induce N-S and E-W extension. Finally, a superimposed stress system is constructed. This stress system shows that the present crustal deformation in Tibet does not produce N-S shortening but generates E-W extension.The results of this paper have provided geodynamical explanations for geological field observations in Tibet and fault plane solutions of earthquakes in the Tibetan side of the India-Eurasia collision. The stress patterns reveal that the cold downwelling mantle convection flow beneath southern Tibet pulls the Indian plate down but applies a bending moment on the end of the plate to uplift and support the mass of the Himalayas.     

Tibetan Plateau: An evolutionary junction for the history of modern biodiversity

Holding particular biological resources, the Tibetan Plateau is a unique geologic-geographic-biotic interactively unite and hence play an important role in the global biodiversity domain. The Tibetan Plateau has undergone vigorous environmental changes since the Cenozoic, and played roles switching from "a paradise of tropical animals and plants" to "the cradle of Ice Age mammalian fauna". Recent significant paleontological discoveries have refined a big picture of the evolutionary history of biodiversity on that plateau against the backdrop of major environmental changes, and paved the way for the assessment of its far-reaching impact upon the biota around the plateau and even in more remote regions. Here, based on the newly reported fossils from the Tibetan Plateau which include diverse animals and plants, we present a general review of the changing biodiversity on the Tibetan Plateau and its influence in a global scale. We define the Tibetan Plateau as a junction station of the history of modern biodiversity, whose performance can be categorized in the following three patterns:(1) Local origination of endemism;(2) Local origination and "Out of Tibet";(3) Intercontinental dispersal via Tibet. The first pattern is exemplified by the snow carps, the major component of the freshwater fish fauna on the plateau, whose temporal distribution pattern of the fossil schizothoracines approximately mirrors the spatial distribution pattern of their living counterparts. Through ascent with modification, their history reflects the biological responses to the stepwise uplift of the Tibetan Plateau. The second pattern is represented by the dispersal history of some mammals since the Pliocene and some plants. The ancestors of some Ice Age mammals, e.g., the wholly rhino,Arctic fox, and argali sheep first originated and evolved in the uplifted and frozen Tibet during the Pliocene, and then migrated toward the Arctic regions or even the North American continent at beginning of the Ice Age; the ancestor of pantherines(big cats) first rose in Tibetan Plateau during the Pliocene, followed by the disperse of its descendants to other parts of Asia, Africa,North and South America to play as top predators of the local ecosystems. The early members of some plants, e.g., Elaeagnaceae appeared in Tibet during the Late Eocene and then dispersed and were widely distributed to other regions. The last pattern is typified by the history of the tree of heaven(Ailanthus) and climbing perch. Ailanthus originated in the Indian subcontinent, then colonized into Tibet after the Indian-Asian plate collision, and dispersed therefrom to East Asia, Europe and even North America. The climbing perches among freshwater fishes probably rose in Southeast Asia during the Middle Eocene, dispersed to Tibet and then migrated into Africa via the docked India. These cases highlight the role of Tibet, which was involved in the continental collision, in the intercontinental biotic interchanges. The three evolutionary patterns above reflect both the history of biodiversity on the plateau and the biological and environmental effects of tectonic uplift.     

Azimuthal anisotropy of Rayleigh waves beneath the Tibetan Plateau and adjacent areas

The crustal and upper mantle azimuthal anisotropy of the Tibetan Plateau and adjacent areas was studied by Rayleigh wave tomography. We collected sufficient broadband digital seismograms trav-ersing the Tibetan Plateau and adjacent areas from available stations, including especially some data from the temporary stations newly deployed in Yunnan, eastern Tibet, and western Sichuan. They made an adequate path coverage in most regions to achieve a reasonable resolution for the inversion. The model resolution tests show that the anisotropic features of scope greater than 400 km and strength greater than 2% are reliable. The azimuthal anisotropy pattern inside the Tibetan Plateau was similar to the characteristic of tectonic partition. The crustal anisotropy strength is greater than 2% in most re-gions of East Tibet, and the anisotropy shows clockwise rotation surrounding the eastern Himalayan syntaxis. Vertically, the anisotropy direction indicates a coherent pattern within the upper crust, lower crust, and lithosphere mantle of the Tibetan Plateau, which also is consistent with GPS velocity field and SKS fast polarization directions. The result supports that the crust-mantle deformation beneath the Tibetan Plateau is vertically coherent. The anisotropy strength of crust and lithospheric upper mantle in Yunnan outside the Tibetan Plateau is lower than 2%, so SKS splitting from core-mantle boundary to station should largely be attributed to the anisotropy of asthenosphere.     

Late Cenozoic deformation subsequence in northeastern margin of Tibet —Detrital AFT records from Linxia Basin

Two events of Tibet uplifting are revealed by detrital apatite fission track (AFT) age data from Linxia Basin. They occurred at about 14 and 5.4-8.0 MaBP respectively. We interpret the first one to be related to the uplifting of the northern Tibet, which might have resulted from convectively removing the thickened lower lithosphere. The second one is a result of Laji Mountain uplifting. Numerous studies of the Tibetan Plateau suggest that the onset time of the deformation in the northeastern margin of Tibetan Plateau and the time of Tibet attaining to its present elevation is about 8 MaBP. They are approximately coincident with the uplift of Lajishan Mountain. It suggests that the northeastern margin of Tibet propagated northeastwardly to its present site in about 8 MaBP for accommodating the sustained convergence between India-Eurasia plate and for keeping its high elevation. The active block pattern dominating the strong earthquake distribution of Chinese continent probably formed at about 8.0-5.4 MaBP.

     

青藏高原东北缘远震P波走时层析成像研究

利用青藏高原东北缘地区固定地震台网2010年4月至2015年3月期间记录的远震事件,采用多道波形互相关方法（Multi-Channel Cross-Correlation）拾取了10697个有效P波相对走时残差数据,进而采用FMTT （Fast Marching Teleseismic Tomography）方法获得了青藏高原东北缘上地幔400 km深度范围内的P波速度结构,结果显示：秦祁地块下面存在深达70 km的高速异常,阻断了青藏高原块体中下地壳低速层向东北方向的延伸;40~140 km深度范围内,四川西南部存在一个低速区,该低速区穿过龙门山断裂带进入到四川盆地内部;祁连山造山带东部低速异常区从地壳一直延伸到上地幔400 km处,表明这里可能存在一个上地幔到地壳间的热流通道;松潘-甘孜地块分布大面积的低速异常区,而鄂尔多斯地块西南缘相对速度较高,这与青藏高原为软块体、介质密度低和鄂尔多斯块体为硬块体、介质密度高相吻合.     

Pleistocene magnetic susceptibility and paleomagnetism of the Tibetan loess and its implications on large climatic change events

Ganzi loess represents the oldest Tibetan loess, its formation is the key to determining the readjustment of Tibetan atmospheric circulation and the relationship between Tibetan uplift and global climatic change. Detailed magnetostratigraphic study shows that the Ganzi loess was formed at about 1.13 MaBP. It also reveals that there are two notable climatic events occurring in 0.95–0.92 Ma and 0.65–0.5 Ma respectively. The both demonstrate that the Tibetan atmospheric circulation was readjusted and the Tibetan Plateau entered the cryosphere at 21.13 Ma, and the Tibetan glaciation might reach its maximum at ∼0.65–0.5 Ma.

     

Geophysical evidence for thrusting of crustal materials from orogenic belts over both sides of the Yangtze Block and its geological significance

Based on deep geophysical detections, we have reconstructed the crustal structure from the eastern margin of the Tibetan Plateau to the Jiangnan-Xuefeng orogenic belt. The results suggest that the Yangtze Block was overthrusted by crustal materials in its NW direction from the eastern Tibetan Plateau but in its SE direction from the Jiangnan orogen. These overthrusting effects control the crustal structure from the western Sichuan to the western area of the Jiangnan orogen-Xuefeng orogenic belt. The eastward extruded materials from the eastern Tibetan Plateau were blocked by the rigid basement in the Sichuan Basin, where upper-middle crust was overthrusted whereas the lower crust was underthrusted beneath the Sichuan Basin. The underthrusted unit was absorbed by crustal folding, shortening and thickening in the Yangtze Block, forming the Xiongpo and Longquan Mountains tectonic belts and resulting in the NW-directed thrusting of the Pujiang-Chengdu-Deyang fault, and the western hillsiden fault in the Longquan Mountain. These results provide resolution to the controversy where the eastward extrusion material from the Qinghai-Tibet Plateau had gone. Overall, that Yangtze Block was subjected to thrusting of the crustal materials from the orogenic belts over its both sides. This finding has implications for the study of the intracontinental orogenic mechanism in South China, the reconstruction of tectonic evolutionary history and the kinematics processes during the lateral extrusion of the Tibet Plateau.     

S-wave residuals from earthquakes in the Tibetan region and lateral variations in the upper mantle

Mean S-wave residuals from 46 earthquakes within and on the margins of the Tibetan Plateau exhibit systematic lateral variations that do not correlate well with elevation or with simple aspects of the geologic history. The earliest S waves come from earthquakes in western Tibet, the Karakorum, and the western Himalaya, and the latest come from earthquakes in north-central Tibet. Although S-waves from earthquakes in the Himalaya tend to be early, the east-west variation in residuals across Tibet is at least as large as the north-south difference between the Himalaya and northern Tibet. If the variations in residuals are a reflection of temperature variations in the upper mantle associated with convection, then upwelling beneath north-central Tibet seems to be flanked by downwelling in western, eastern, and probably southern Tibet. This convective flow might reflect the detachment and removal of thickened mantle lithosphere beneath Tibet.     

青藏高原P波速度层析成像与岩石圈结构

利用中国西部地震台网的数据,通过体波层析成像反演了青藏高原及邻域的三维P波速度结构.根据地壳和上地幔的速度变化和构造特征,重点讨论了下地壳流动、地幔上涌、岩石圈减薄以及与藏北新生代火山岩和藏南裂谷系的关系等问题.分析表明,青藏高原中、下地壳平均速度偏低,低速区主要分布在拉萨和羌塘块体内部,随着深度的增加逐渐扩大到松潘—甘孜块体.上述低速区之间多被高速带分隔,暗示地壳中、下部的韧性变形被限制在特定的区域,不太适于产生贯穿整个青藏高原的大规模横向流动.此外,地幔上涌也并非普遍发生于整个青藏高原,而是集中在羌塘、松潘—甘孜以及喜马拉雅东构造结附近,导致上述区域的岩石圈地幔较薄,并且伴生火山活动和岩浆作用.此外,由于印度大陆岩石圈在向北俯冲,板片下沉过程中引起地幔上涌,热流物质有可能上升进入地壳,这一作用对藏北新生代火山岩和藏南裂谷系的形成以及中、下地壳的韧性变形产生了明显的影响.     

Salinity Tolerance and Salinity Induced Changes in Ionic and Metabolite Composition in a Penaeid Prawn,Parapenaeopsis sculptilis (Heller)

Summary: Experiments were carried out to study the salinity tolerance and the impact of salinity changes on ions and metabolite in the body of a marine penaeid prawn, Parapenaeopsis sculptilis. Juveniles of this prawn species have a comparatively wide range of salinity tolerance than adults. Juveniles can tolerate 60 … 100 %, but adults only 100 % seawater concentrations. Behavioural observations showed that the juvenile and adult prawns became inactive with decrease in seawater concentrations followed by paralysis and death. Death occurred probably due to failure of the neuromuscular system. A highly significant variation existed in the amount of sodium, potassium and calcium ions in juveniles as well as adults. Exposure to different seawater concentrations probably caused breakdown of the osmoregulatory mechanism in the prawn body. Protein and carbohydrate decreased in both juvenile and adult prawn body, with the decrease in seawater concentrations indicating the utilization of large amounts of protein and carbohydrate from the internal reserve.     

藏北高原地震活动性特征及其大地构造意义

藏北高原自新生代以来不仅发生了强烈的火山作用,而且现今的地震活动性仍然强烈.本文收集了2011年前藏北高原区发生的地震事件(源自NEIC)及相应的震源机制解数据(源自GCMT),结合地质与地球物理等相关资料,初步分析表明藏北高原地壳整体上处于伸展应力状态.然而,因区域构造应力场及构造环境差异,将藏北高原地震活动区分为两个地震活动区,即西昆仑地震活动区和藏北中部火山岩区.西昆仑区的地壳应力状态呈东西向伸展,而岩石圈地幔部分主要以南北汇聚为主,表明西昆仑区域下的地壳与岩石圈地幔应力状态是解耦的,而这种解耦机制需要更进一步的研究.而在藏北中部火山岩区的地壳的主张应力场为NNE-SSW的走滑和正断层性质的伸展,尽管缺乏该区域下的岩石圈结构特征认识,但是依据幔源性质的钾质和超钾质火山岩成因模式,认为其下的岩石圈地幔也处于伸展状态,该区域下的地壳与岩石圈地幔同处于伸展应力环境中,表明藏北火山岩区下的结构特征更加复杂,亟待开展相关探测与研究.     

无限元法在深覆盖层土石坝动力分析中的应用

以复杂地质条件的西藏高原地区旁多水电站实际工程为背景,探讨了有限元法与无限元法在深覆盖层悬挂式防渗墙土石坝结构非线性动力分析中的差异,分析和比较了无限元法和有限元法在西藏高原旁多水电站土石坝结构三维模型地震动响应的计算结果,验证了引入无限元法模拟西藏高原地区地基中复杂地质条件下的无限域或半无限域问题的可靠性和精确性。结果表明:在西藏高原地区复杂地质条件下,无限元法相比有限元法能量弥散现象较为明显。通过分析得到了西藏高原具有深覆盖层坝体结构地震动响应的规律性分析结果,为无限元法在西藏高原地区此类工程中的应用提供参考。     

藏北色林错流域的水文特征

本文报道了1997年降1998年夏季对藏北色林错等水体水文特征的考察情况,结果表明,色林错是一个大型深水湖泊,表层水温在下午4：30左右达到最高,清晨7：30左右时最低,浅水区域表层湖水在6月份的极端最高水温为21．2℃,极端最低水温为11．0℃,而日平均水温变幅仅5．6℃,其幅度大于在同一时段湖区内不同区域之间表层水温的变化,色林错湖水的pH值较高咪9．19－9．66;表层水的pH昼夜变化较小,仅0．15,最高值出现在凌晨,同时水体不同区域及深度的pH值基本一致,其溶解氧变化在4．62－5．12mg/L,而且不同深度水层之间的变幅较小,仅0．03－0．35mg/L;但其湖汊浆东如瑞溶解氧的昼认变幅为4．58－5．59mg/l;盐度的日变幅为1．60％－2．20％,考察表明,藏北水体的盐分有一个从河流到湖泊、以及由流水向静水富集的趋势;鱼类的分布与水体盐分的含量密切相关,即鱼类随着水体盐分的增加而消失,代之以嗜盐性卤虫的出现及大量繁衍。     

Regularities in the diurnal variations of hydrochemical characteristics in the coastal zone of a sea

Amur Bay (Sea of Japan) is used as an example to show that the range of diurnal variations of hydrochemical characteristics in the coastal zone of a sea subject to the effect of continental runoff features some regularities. Specifically, variations of water salinity in the surface frontal zone of estuaries exponentially increase toward the river and reach the largest magnitude in the zone of high longitudinal gradients, where diurnal salinity distributions are found to deviate from the normal law.     

青藏高原上地幔速度结构及其动力学性质

利用地震层析成像结果分析了中国西部地区的上地幔速度结构,发现青藏高原北部至东南边缘上地幔顶部速度普遍偏低;随着深度的增加,低速区主要分布在羌塘、松潘—甘孜和云南西部地区,而印度大陆、塔里木、柴达木、鄂尔多斯和四川盆地均显示出较高的速度.上述速度分布与青藏高原及周边地区的岩石层结构和深部动力性质密切相关:其中羌塘地区的低速异常反映了青藏北部的地幔上涌和局部熔融,起因于印度大陆岩石层的向北俯冲;松潘—甘孜地区的低速异常与青藏东部的深层物质流动及四川盆地刚性岩石层的阻挡有关;而滇西地区的低速异常可能受到印缅块体向东俯冲作用的影响.以上三个区域构成青藏高原和周边地区的主要地幔异常区.相比之下,印度大陆、塔里木、柴达木、鄂尔多斯和四川盆地的高速异常反映了大陆构造稳定地区的岩石层地幔特点.根据速度变化推测,地幔上涌和韧性变形并非贯穿整个青藏高原,而是主要集中在羌塘、松潘—甘孜和滇西地区,上述构造效应不仅导致岩石层厚度减薄且引发了火山和岩浆活动.     

利用Lg波Q值反双台层析成像方法研究青藏高原南部地区的地壳衰减

首次基于2017—2019年西藏自治区区域台网27个宽频带固定台站记录的757次地震的波形资料,利用反双台法开展了青藏高原南部地区1 Hz的Lg波Q值层析成像研究.研究中采用3.5—2.4 km/s的速度窗截取了1981条Lg波,计算得到13543条路径上的Q值,测试了1°×1°和0.5°×0.5°网格下的棋盘格恢复情...