藏北羌塘牧民家庭牲畜存出栏权衡及影响因素分析

本研究以藏北牧民家庭为研究对象,通过半结构式访谈调查高寒草甸、高寒草原和荒漠草原区牧户牲畜存出栏规模结构及其影响因素。结果表明:荒漠草原户均牲畜存/出栏规模(254.8/48.6 SSU)显著高于高寒草甸(191.55/33.22 SSU)和高寒草原(189.89/33.49 SSU);对牧户牲畜存栏规模影响最大的因素依次为单位面积产草量(高寒草甸)、家庭规模(高寒草原)和草畜平衡草场面积(荒漠草原),可以解释其变异的10.78%,19.40%和15.99%;对牧户牲畜出栏规模影响最大的因素依次为草畜平衡草场面积(高寒草甸)、家庭规模(高寒草原)和劳动力数量(荒漠草原),可以解释其变异的15.01%,11.20%和23.55%。综上所述,藏北高原牧民户均牲畜存/出栏规模和结构在不同草地类型之间存在明显差异,且受到自然和人文因素的双重影响。在未来制定草原生态保护政策时需要重点考虑资源禀赋和利用方式的差异。

藏北羌塘中部果干加年山早古生代堆晶辉长岩的锆石SHRIMP U-Pb年龄--兼论原-古特提斯洋的演化

位于羌塘中部龙木错-双湖缝合带中的果干加年山早古生代堆晶岩,主要由辉石橄榄岩、堆晶辉石岩、堆晶辉长岩、斜长岩等岩石类型组成。对堆晶辉长岩中锆石的矿物学与年代学研究表明,堆晶辉长岩中发育3种内部结构特征的锆石晶体,锆石Th、U含量和Th/U值揭示了同一岩浆系统中结晶形成的岩浆锆石。获得堆晶辉长岩SHRIMP锆石U-Pb谐和年龄461Ma±7Ma(MSWD=1.3)、431.7Ma±6.9Ma(MSWD=0.54),分别代表了青藏高原中部地区原-古特提斯洋扩张过程中早期(中奥陶世Darriwilian阶晚期)、晚期(早志留世Telychian阶中期)的岩浆作用事件。果干加年山早古生代堆晶岩具有MORB的特征,代表了龙木错-双湖缝合带中残存的早古生代蛇绿岩,也是青藏高原中南部地区目前为止认知时代最早的原-古特提斯洋壳的残迹。羌塘中部早古生代蛇绿岩的确定及其年代学的约束,使得龙木错-双湖特提斯洋盆的形成时代至少可以追溯到中奥陶世—早志留世,并推论龙木错-双湖缝合带、南羌塘古生代增生楔及其中生代盆地和班公湖-怒江缝合带共同构成了青藏高原特提斯大洋最终消亡的巨型缝合带,晚古生代原-古特提斯洋向南的俯冲消减导致了冈底斯带石炭纪—二叠纪岛弧型火山岩、二叠纪花岗闪长岩和大洋俯冲型榴辉岩的形成。

藏北羌塘中部吉瓦地热田的特征及其资源评价

吉瓦温泉位于西藏尼玛县绒马乡吉瓦村北。温泉出露于一个新生代断陷盆地之中,受江爱藏布活动断裂带的控制。地下热水矿化度为5.54×103～5.58×103mg/L,水化学类型属Na-Cl·HCO3型。温泉水中H2SiO3、Li+、F-等含量较高,这3项指标满足医疗矿水的标准。热水系统的热源来自于地壳中的部分熔融层,热水的补给来源主要为大气降水,伴有深部热液加入。混合模型研究显示,温泉水为地下热水和冷水的混合物,冷水占的比例介于77%～95%之间,混合水的循环年龄约31a,利用SiO2温标法计算出浅部热储温度为120℃,深度为832m。混合前热水温度为215～280℃,对应深部热储深度为1466～1900m。吉瓦热田面积约6km2,天然放热量为7.53×1013J/a,地热资源量为32606×1014J。

藏北羌塘奥陶纪平行不整合面的厘定及其构造意义

西藏羌塘块体有无变质基底、其前新生代构造属性与演化过程是长期争论的议题。本文报道南羌塘块体北部,中、上奥陶统塔石山组底砾岩平行不整合于浅变质中厚层石英砂岩夹薄层泥灰岩之上。近600粒碎屑锆石测年结果表明浅变质石英砂岩的最大沉积年龄为527±7Ma,300余粒碎屑锆石测年结果表明塔石山组底部石英砂岩的最大沉积年龄为471±6Ma。不整合面上、下石英砂岩最大沉积年龄之差达56Myr,表明这两套石英砂岩之间存在明显的沉积间断,证实了该平行不整合面的时代为奥陶纪早期。另一独立的证据是在邻区发现了早奥陶世花岗岩类岩石（471～477Ma）侵位于该浅变质石英岩,因此将不整合面之下的浅变质石英岩暂命名为荣玛组,归入寒武系地层。阴极发光与年代学研究进一步表明不整合面之上的碎屑锆石主要来源于在“泛非”运动晚期形成的结晶岩,为近源锆石,表明“泛非运动”晚期所形成的结晶岩在奥陶纪早期就已隆升,遭受剥蚀,为区内中上奥陶统沉积岩的形成提供物质来源。该奥陶纪平行不整合面的发现,表明南羌塘块体与喜马拉雅、拉萨等块体相似,同属冈瓦纳大陆体系。南、北羌塘早古生代地层系统之间的显著差异表明在寒武-奥陶纪之交,南、北羌塘块体就已被古大洋盆分隔开,开始各自独立演化。

藏北羌塘丁固—加措地区康托组的时代

自西藏区域地质调查大队创建康托组以来,康托组岩石地层单位广泛应用于羌塘地区,普遍认为其时代为新近纪。笔者于丁固—加措地区的康托组地层中采获古近纪轮藻化石Obtusocharasp.,O.lanpingensis,Gyrogonaqinajiangica和部分孢粉化石,并在康托组底部安山岩中获K-Ar年龄65.1～66.5Ma。上述轮藻组合与同位素年龄指示的地层时代为古新世—始新世,据此将测区康托组的时代确定为古近纪。由于测区康托组之上被唢纳湖组或鱼鳞山组角度不整合覆盖,因此康托组时代的确定不仅进一步完善了测区新生代地层系统,还指示测区在康托组与唢纳湖组或鱼鳞山组之间发生了一次强烈的构造运动。

藏北羌塘本松错片麻岩穹隆的厘定及稀有金属找矿前景

本文在详实的野外地质调查基础上,报道了新厘定的藏北羌塘本松错片麻岩穹隆的结构组成。结果表明,本松错片麻岩穹隆由核-幔-边三部分组成,由内到外依次包括核部花岗伟晶岩、幔部花岗质片麻岩和边部变质增生杂岩。并结合前人的研究成果,对该穹隆的形成时代进行探讨。在该穹隆东部厘定出一系列向东剪切拆离断层,我们认为该穹隆为印支期花岗岩侵入时经类似于变质核杂岩的构造作用形成。此外,我们在本松错北部发现大量含电气石(及锂云母?)的伟晶岩,推测该地区具有稀有金属找矿前景。

羌塘盆地双湖地区早中侏罗世过渡期碳同位素波动及成因研究

藏北双湖县巴岭乡地区出露一套深水相黑色页岩地层,包括下侏罗统曲色组和中侏罗统色哇组二个组地层单元。根据菊石化石控制的生物地层时代,下伏曲色组划归PliensbachianToarcian阶,上覆色哇组级代表AalenianBajocian期沉积,二者之间为连续沉积,是目前西藏特提斯域菊石化石控制程度最高的中下侏罗统地层。野外实测了索布查J_(2)/J_(1)界线剖面,按2m间距采集了148件样品,室内开展了无机碳(δ^(13) C_(carb))和有机碳(δ^(13) C_(kero))分析,目的是揭示早侏罗世末期到中侏罗世初期这一时段的古海洋演化过程。研究结果表明,曲色组沉积期古海水δ^(13) C_(DIC)偏正,而色哇组δ^(13) C_(DIC)偏负,J_(2)/J_(1)界线上下δ^(13) C_(carb)值显示阶步式负向偏移的特点。根据相关分馏方程计算,Toarcian期海洋浮游植物繁盛,δ^(13) C_(DIC)偏正,海水营养盐NO_(3)浓度偏低,而Aalenian期海洋浮游植物衰减,δ^(13) C_(DIC)偏低,NO_(3)浓度升高。沉积有机质或干酪根碳同位素δ^(13) C_(kero)在J_(2)/J_(1)界线上下与δ^(13) C_(carb)变化趋势一致,也具有由高值逐渐偏低的特点,但δ^(13) C_(carb)和δ^(13) C_(kero)变化曲线的波峰和波谷并不同步,这是因为海源和陆源有机质相对含量高低变化所致。文中根据碳同位素质量平衡方程,定量的描述了索布查界线剖面陆源和海源有机质比例的变化过程,讨论了曲色组和色哇组烃源岩在油气勘探中的意义。

北羌塘沃若山地区火山岩年代学及区域地球化学对比--对晚三叠世火山-沉积事件的启示

藏北羌塘沃若山地区三叠系肖茶卡组之上不整合沉积超覆了一套沉火山碎屑岩夹火山岩地层,该套地层底部的玻屑凝灰岩夹层的SHRIMP锆石U-Pb年龄为(216.1±4.5)Ma,该年龄代表了沃若山地区晚三叠世火山-沉积事件的时代,它与最近获得的羌塘盆地广泛分布的那底岗日、石水河等地区的那底岗日组火山岩的形成时代基本一致,同属晚三叠世.微量元素及同位素地球化学特征表明,沃若山地区火山岩的地球化学特征与其相邻的那底岗日、石水河等地区的那底岗日组火山岩十分相似,表明该时期羌塘地区的火山岩可能具有相同的岩浆源区和相似的构造环境.羌塘盆地晚三叠世大规模火山喷发与火山-沉积事件的正确认识,对于探讨东特提斯域晚三叠世生物绝灭、气候变化与海退事件具有重要的意义,同时,对于了解晚三叠世-侏罗纪北羌塘地区新一轮盆地演化的开启时间、盆地性质及沉积特征也具有重要的意义.

当惹雍错的苦修岁月

当惹雍错是镶嵌在藏北羌塘高原中的一个天然咸水湖，形成于300万年前。湖边的穹宗古堡遗址离最近的村庄文布南也有25公里。这里是苯教的发源地，因而穹宗的半山腰散落地住着几位苦修僧侣。

我的夏季牧场

许多人喜欢海洋,依恋内心被浪涛抚平的安宁。我却更钟意草原,因为那是可以到达的地方。火车轰隆隆在藏北羌塘上推进,抵达那曲时是清晨。天空深处一片黛青,由西向东向浅蓝渐变,视野尽头堆积着层叠的云。待到苍穹中铺开万道霞光,新的一天便拉开序幕。无垠的草原上星辰般散落着无数小水洼,形成一面面镜子,将第一缕阳光反射了千万遍。

Paleomagnetic data from the Late Carboniferous-Late Permian rocks in eastern Tibet and their implications for tectonic evolution of the northern Qiangtang-Qamdo block

We report paleomagnetic results from the Late Carboniferous-Late Permian strata in eastern Tibet (China), and aim to clarify the tectonic and paleogeographic evolution of the northern Qiangtang-Qamdo block, which is the key to the study of plate boundary between the Gondwanaland and the Eurasia during the late Paleozoic. Two hundred and nineteen samples-including limestone, muddy siltstone, basalt, lava, and tuff-were collected at 24 sites in the Upper Carboniferous and Middle-Upper Permian successions. A systematic study of rock magnetism and paleomagnetism yields three reliable paleomagnetic pole positions. Both hematite and magnetite occurred in the Late Carboniferous limestone samples. The demagnetization curve shows a characteristic double-component, with the remanent magnetization (ChRM) exhibiting a positive polarity (negative inclination). In the Late Permian limestone, tuff, and basalt, magnetic information were recorded primarily in magnetite, although a small fraction of them was found in hematite in basalt. The demagnetization curve illustrates a double or single component, with the ChRM showing a negative polarity (positive inclination), which has passed the classic fold test successfully. The single polarity features of the ChRM directions of the Late Carboniferous and Middle-Late Permian rocks are respectively related to the Kiaman positive and reversed polarities under the stratigraphic coordinates. This, in turn, indicates that both ChRMs directions represent the original remanence directions. By comparison with the previously published paleomagnetic results from the late Paleozoic rocks in the northern Qiangtang Range, we suggest that: (1) Qamdo and northern Qiangtang block were independent of each other during the Late Carboniferous to the Early Permian periods. The north Lancangjiang ocean basin between the two blocks may have closed before the Middle Permian and been involved in the continent-continent collision stage in the Late Permian-Early Triassic periods. (2) The northern Qiangtang-Qamdo Block paleogeographically was situated at low to intermediate latitudes in the Southern Hemisphere in the Late Carboniferous-Late Permian periods, and began to displace northward in the Early Triassic, with an amount of more than 5000 km northward transport from its current location.

Paleomagnetic results of Late Paleozoic rocks from northern Qiangtang Block in Qinghai-Tibet Plateau, China

Tectonic evolution of the Tethys and the boundary between the Gondwanaland and the Eurasia during the Carboniferous and Permian remain hotly debated. Qiangtang region in the Qinghai-Tibet Plateau may be a key place to study these problems. A paleomagnetic study was conducted on the Late Paleozoic rocks in the northern Qiangtang region （33.7°N, 86.7°W）, Tibet. Two sites （21 samples） in the Upper Carboniferous, eleven sites （101 samples） in the Permian, and two sites （16 samples） in the Lower Triassic were investigated. The rock magnetic data revealed hematite and magnetite as the main magnetic carders. In stepwise thermal demagnetization and/or combined alternating field （AC） demagnetization, two characteristic components in the majority of the samples were identified as （1） the Low-temperature Component （LTC）, characterized by northerly decli- nation and moderate to steep inclination, corresponding to a pole position overlay with the present North Pole. A minority of the samples present single component, and their directions are the same as （2） the High-temperature Component （HTC） of double components. The combined single-component and HTC data of the Permian can pass the R-test at 95% level and the F-test at 99% level, as well as the BC-test. The pole position from the Late Carboniferous is at 31.8°S, 45.7°E with dp=2.1, dm=3.9, that from the Early and Middle （Late） Permian is at 31.7°S, 46.8°E with @=9.2, dm=16.9 （34.4°N, 54.1°E with dp=6.9, dm=1 2.5） respectively, and that from the Early Triassic is at 16.9°S, 22.5°E with dp=4.9, dm=9.2. These pole positions are different from the other poles for the Qiangtang Block, which suggests the single-component and HTC directions are probably a primary magnetization and the northern Qiangtang Block was paleogeographically situated at low latitudes in the Northern Hemisphere in the Late Paleozoic.