华北地台东部石炭系—二叠系优质煤储层形成分布控制因素

优质煤储层在此指厚度大、分布广、储集物性好的煤层。沉积相对优质煤储层的形成和分布有重要控制作用。通过浅海和泻湖淤积填平发育起来的潮坪环境和三角洲环境是最有利的优质煤储层形成环境,煤储层厚度大、分布广。沉积环境对煤储层中的灰分含量和镜质组含量有重要影响,而灰分含量和镜质组含量又直接影响煤储层的储集物性。灰分充填了煤储层中的孔隙,其含量越高,储集物性越差;镜质组有利于割理的形成,其含量越高,储集物性越好。由于在灰分含量、煤岩显微组分等方面的差异,潮坪环境沉积的煤储层的储集物性优于三角洲的煤储层,下三角洲平原沉积的煤储层优于上三角洲平原沉积的煤储层。海平面变化对优质煤储层的形成和分布也有重要控制作用。高位体系煤储层富集,单层厚度大,横向分布相当稳定,尤其是高位体系域晚期,是形成优质煤储层最有利的层位。而水进体系域煤储层稀少,单层厚度小,横向分布不稳定,不利于优质煤储层形成。     

Dehydration and melting during continental collision: Constraints from element and isotope geochemistry of low-T/UHP granitic gneiss in the Dabie orogen

A combined study of petrography, whole-rock major and trace elements as well as Rb?Sr and Sm?Nd isotopes, and mineral oxygen isotopes was carried out for two groups of low-T/UHP granitic gneiss in the Dabie orogen. The results demonstrate that metamorphic dehydration and partial melting occurred during exhumation of deeply subducted continent. Zircon δ¹⁸O values of ? 2.8 to + 4.7‰ for the gneiss are all lower than normal mantle values of 5.3 ± 0.3‰, consistent with ¹⁸O depletion of protolith due to high-T meteoric-hydrothermal alteration at mid-Neoproterozoic. Most samples have extremely low ⁸⁷Sr/⁸⁶Sr ratios at t₁ = 780 Ma, but very high ⁸⁷Sr/⁸⁶Sr ratios at t₂ = 230 Ma. This suggests intensive fluid disturbance due to the hydrothermal alteration of protoliths during Neoproterozoic magma emplacement and the metamorphic dehydration during Triassic continental collision. Rb–Sr isotopes, Th/Ta vs. La/Ta and Th/Hf vs. La/Nb relationships suggest that Group I gneiss experienced lower degrees of hydrothermal alteration, but higher degrees of dehydration, than Group II gneiss. The two groups of gneiss have similar patterns of REE and trace element partition. Group I gneiss displays good correlations between Nb and LREEs but no correlations between Nb and LILEs (Rb, Ba, Pb, Th and U), indicating differential mobilities of LILEs during the dehydration. Thus the correlation between Nb and LREEs is inherited from protolith rather than caused by metamorphic modification. Relative to Group I gneiss, Group II gneiss has stronger negative Eu anomaly, lower contents of Sr and Ba but higher contents of Rb, Th and U. In particular, Nb correlates with LILEs (e.g., Rb, Sr, Ba, Th and U), but not with LREEs (La and Ce). This may indicate decoupling between the dehydration and LILEs transport during continental collision. Furthermore, dehydration melting may have occurred due to breakdown of muscovite during “hot” exhumation. Group II gneiss has extremely low contents of FeO + MgO + TiO₂ (1.04 to 2.08 wt.%), high SiO₂ contents of 75.33 to 78.23 wt%, and high total alkali (Na₂O + K₂O) contents (7.52 to 8.92 wt.%), comparable with compositions predicted from partial melting of felsic rocks by experimental studies. Almost no UHP metamorphic minerals survived; felsic veins of fine-grain minerals occurs locally between coarse-grain minerals, resulting in a kind of metatexite migmatites due to dehydration melting without considerable escape of felsic melts from the host gneiss. In contrast, Group I gneiss only shows metamorphic dehydration. Therefore, the two groups of gneiss show contrasting behaviors of fluid–rock interaction during the continental collision.     

Zircon U–Pb and Hf isotopic study of gneissic rocks from the Chinese Altai: Progressive accretionary history in the early to middle Palaeozoic

Gneissic rocks in the Chinese Altai Mountains have been interpreted as either Paleozoic metasedimentary rocks or Precambrian basement. This study reports geochemical and geochronological data for banded paragneisses and associated gneissic granitoids collected along a NE–SW traverse in the northwestern Chinese Altai. Petrological and geochemical data suggest that the protoliths of the banded gneisses were possibly immature sediments with significant volcanic input and that the gneissic granitoids were derived from I-type granites formed in a subduction environment. Three types of morphological features can be recognized in zircons from the banded gneisses and are interpreted to correlate with different sources. Zircons from five samples of banded paragneiss cluster predominantly between 466 and 528 Ma, some give Neoproterozoic ages, and a few yield discordant Paleoproterozoic to Archean ages. Zircon Hf isotopic compositions indicate that both juvenile/mantle and crust materials were involved in the generation of the source rocks from which these zircons were derived. In contrast, zircons occur ubiquitously as elongated euhedral prismatic crystals in the four samples of the gneissic granitoids, and define single populations for each sample with mean ages between 380 and 453 Ma. The general absence of Precambrian inheritance and positive zircon ?Hf values for these granitoids suggest insignificant crustal contribution to the generation of the precursor magmas. Our data can be interpreted in terms of a progressive accretionary history in early to middle Palaeozoic times, and the Chinese Altai may possibly represent a magmatic arc built on a continental margin dominated by Neoproterozoic rocks.     

牛庄洼陷沙河街组超压系统发育特征及其演化

东营凹陷牛庄洼陷沙河街组发育有超压系统,这对油气运移和聚集过程有着重要的影响。在对超压系统现今发育特征研究的基础上,本文运用约束下数值模拟方法对牛庄洼陷超压系统的演化规律进行研究,并探讨了超压系统的主要形成机制。牛庄洼陷在沙河街组四段、沙河街组三段的下亚段和中亚段存在着超压系统,最大压力系数可以达到1.8,最大剩余压力超过了20MPa。自沙三段上亚段沉积期开始,超压系统开始发育。到东营组沉积期末,超压系统经历了大约10Ma的泄压过程。自新近系馆陶组沉积期,超压系统再次迅速增压,逐渐接近现今发育状况。上覆地层沙三段上亚段高沉积速率导致了超压系统的形成和早期剩余压力的增加,而水热增压和烃类物质大量生成联合造成超压系统晚期迅速增压。超压系统演化规律揭示出在油气主要运移期研究区古异常流体压力的分布状况,这为进一步开展牛庄洼陷油气运移和聚集过程的动力学研究提供了理论依据。     

辽东湾凝析气田超压成因及侧向传递机制初探

位于辽东湾西部低凸起北端的JZ20-2超压凝析气田,离供烃中心较远,压力系数却达到1.56~1.7,这在我国东部裂谷盆地比较少见。经过综合分析,作者认为JZ20-2凝析气田异常高压的形成与其所处的特殊地质背景紧密相关,辽中凹陷沙河街组三段超压凝析油气沿不整合面、砂体输导通道向辽东湾西部低凸起的运移、充注和能量的侧向传递是JZ20-2凝析气田异常高压形成的根本原因,而上覆东营组二段下亚段-东营组三段巨厚的强超压泥岩封盖和辽西3号边界断层侧向遮挡共同构成的优越封闭环境是超压保存的必要条件。本文分析了该气田超压特征及其远距离超压侧向传递的成因机制,不仅有助于揭示辽东湾西部低凸起超压流体运移聚集的规律和成藏作用,而且可能提供了一个超压远距离侧向传递的典型实例。     

青藏高原中、东部局地因素对地温的双重影响(Ⅰ): 植被和雪盖

青藏高原冻土区地温既受海拔、纬度和经度(干燥度)区域地带性规律控制, 同时它又受植被、雪盖、砂层、 水被和地质构造等局地因素的显著影响. 局地因素对地温的影响具有双重性: 在不同域值条件下, 它可增高或降低地温. 地温随植被覆盖度减小而逐渐增高, 但覆盖度减到0～20%时, 地温反而降低. 在青藏高原东部、南部和腹部的高山区, 冷季降雪多, 很多地段为稳定积雪区, 雪盖厚, 持续时间长, 对浅层地温起保温作用;而高原腹部的高平原、河谷和盆地冷季降雪较少, 雪盖薄, 持续时间较短, 一般保温作用微弱. 当雪盖厚度超过20 cm以后, 保温作用即开始增强;在暖季因积雪存在时间短, 雪盖薄, 短期内对浅层地温起冷却作用. 总之, 每种局地因素迫使地温向相反方向转化阶段是一个区间值, 为渐变过程. 随时空尺度变化, 局地因素的影响变化很大. 有些地段, 几种局地因素共同作用, 加上活动构造和地形、地貌等的影响, 使地温的时空分布和局地因素对其影响或控制变得错综复杂. 因此, 研究和预测地温特征和变化趋势, 需要在监测植被和积雪作用的基础上进行参数选择、 验证和优化.     

寒区线性工程沿线冻土区的植被恢复

寒区油气管道、公路、铁路等线性工程占地、建设和开挖对沿线寒区生态环境是一个切割、破碎的过程, 对自然植被和下伏冻土造成了很大的扰动. 管道泄露引发的油污还可引起植被的退化和死亡. 植被覆盖层破坏后改变了原有的地气界面之间的水、热交换条件和力学性质, 反过来又可加速引发下伏冻土和线性工程地基的退化. 基于保护线性工程地基及下伏冻土的目的, 同时顺应环境保护的要求, 目前就寒区线性工程的植被恢复问题已经有许多探索和实践. 当前, 寒区植被恢复注重最低限度的人为介入干预下的自然恢复, 根据线性工程沿线土壤、湿度、营养条件、物种分布和丰度, 视具体情况选择物种, 确定建植方法. 阿拉斯加管道和青藏铁路植被恢复上的经验和方法, 可为拟建的冻土区中俄输油管道项目沿线的植被恢复问题提供科学的参考和借鉴.     

祁连山不同植被类型对积雪消融的影响

为研究祁连山植被对积雪消融的影响, 利用人工调查积雪深度逐日变化量和积雪盖度变化, 并结合空气雪面感热通量(SH)观测, 对祁连山水源林生态站排露沟流域海拔2 600～2 700 m青海云杉林、灌丛林、林缘、阳坡草地在2003-2007年的积雪消融进行了研究, 每年的观测从10月降雪开始到翌年5月积雪消融完结束, 共获取数据134 400个. 结果表明: 当SH<0时, 积雪消融停止;当SH>0时, 积雪消融开始;植被可以减缓积雪消融速率, 有植被的地方消融速率减慢, 反之则加快;不同植被消融速率大小顺序为草地>林缘>灌木林>乔木林;同一植被、不同坡向消融速率不同, 半阳坡云杉林＞半阴坡云杉林＞阴坡云杉林. 积雪含水率随气温升高而增大, 1月融化积雪占整个积雪的5%, 2月增大到28%, 大量积雪在3月消融, 占55%. 从坡位看, 下坡消融速率最大;在一个垂直带上, 低海拔消融速率大于高海拔. 温度是影响积雪消融的主要因子, 积雪消融速率随温度升高而增大, 反之则减小.     

亚洲中部干旱区在20世纪两次暖期的表现

利用亚洲中部干旱区1901-2002年近100 a气温及北半球海平面气压、冬季西伯利亚高压强度指数、西风指数资料,分析了20世纪全球变暖的两个较明显时期在该干旱区的响应特征,以及大气环流变化和太阳活动对干旱区气温异常的影响.结果表明:亚洲中部干旱区对20世纪全球发生的两次暖期的响应特征是有显著差异的.对1920-1940年代全球发生的第一次暖期,亚洲中部干旱区整体并没有响应,仅在其东部的季风影响边缘区有响应;而对1970年代以后发生的第二次暖期,亚洲中部干旱区整体都作出了响应.冰岛低压的异常加深、同时北大西洋亚速尔高压的显著增强,西伯利亚高压强度指数的异常减弱,以及西风指数的异常增强是导致亚洲中部干旱区气温偏高的可能原因,可以初步解释研究区整体对20世纪全球两次暖期响应不同的原因.太阳活动作为外部影响因子之一,对干旱区气温的影响是阶段性的,且在百年时间尺度上,二者并没有显著的相关性.     

东北多年冻土区埋地输油管道周围温度场特征非线性分析

为解决冻土区输油管道周围土壤的温度计算问题,根据考虑相变瞬态温度场的控制微分方程,应用Galerkin法推导出了二维温度场的有限元计算公式.以东北多年冻土区中俄原油管道工程为背景,根据该工程区的冻土条件和气候条件,应用该方法对温热型输油管道土壤温度场进行了计算预报与对比分析.结果表明:对于输送油温为15 ℃、直径为0.914 m以及管顶埋深为2.0 m的管道,在没有铺设保温材料情况下,管顶之上的土壤在管道运行的第1年就达到热平衡状态,同时土壤融化速率在第1年达到最大,随后4a时间里迅速减小,第5年后融化速率变化趋于稳定;管道运行一段时间后,管道周围的融化圈随冷暖季节的变化呈交替式的扩展;在管道运行30 a后,融深＞10 m,即管底下的融化层厚＞7 m,而在铺设5～8 cm的聚氨酯保温材料后,融深控制在3.08～3.88 m,即管底下融化层厚为0.2～1.0 m.因此,合理使用保温方法能有效防止冻土区管道冻害的发生,同时达到保护冻土环境的目的.