准噶尔盆地南缘天然气成藏及勘探方向

准噶尔盆地南缘地区与塔里木库车坳陷有着相似的沉积地层和构造演化历史,但是天然气勘探始终未取得重大突破。本文在南缘地区天然气成因类型与气源判识的基础上,分析该地区天然气成藏条件,探讨有利勘探方向与目标层系。结果表明,南缘地区天然气存在煤型气、混合气与油型气三类,且以煤型气和混合气为主;侏罗纪煤系为该地区主要的天然气源岩,其大量生气期与背斜构造形成期相匹配,构成最佳源灶-圈闭成藏组合;二叠系湖相和上三叠统湖相-湖沼相烃源岩也是重要的天然气源岩,其主要生气期在中部地区早于绝大多数背斜构造形成期,而在西部地区与背斜构造形成期相匹配。南缘地区生烃物质基础好于库车坳陷,只是主要气源岩侏罗纪煤系的成熟度略低于库车坳陷,盖层封盖性和储层发育规模略逊于库车坳陷,但仍具备形成大规模油气田的成藏条件。深层二叠系-侏罗系-白垩系成藏组合是最为有利的天然气勘探目标层系,西部是寻找和发现侏罗纪煤系和二叠系湖相油气藏的有利目标区域,中部是寻找和发现侏罗纪煤系天然气藏的有利目标区域。中浅层白垩系-新近系成藏组合是次要的天然气勘探目标层系,具有寻找和发现一定规模天然气藏的潜力。高探1井获得重大突破充分表明制约南缘天然气勘探大发现的因素不是气源规模、运移通道、储层物性和盖层封闭性,而是有效圈闭的落实、钻井工程技术及勘探工作量的投入。     

鄂尔多斯盆地靖边气田沟槽与裂缝的配置关系对天然气富集程度的影响

陕200井区是在鄂尔多斯盆地靖边气田发现的一批具有潜在储量的区块,对该井区天然气富集规律的认识有助于更好地进行勘探开发。研究认为:沟槽与裂缝的不同配置关系对马五段各小层天然气的富集程度产生不同的影响,上古生界天然气首先沿沟槽垂向穿层运移至奥陶系下古生界马五段各个小层中,然后再沿裂缝转为小层内的侧向运移;沟槽发育越完善,裂缝密度越大,则天然气富集程度越好。马五1亚段、马五2亚段在沟槽和裂缝的双重作用下,其含气饱和度高于仅有裂缝的马五41小层,研究区各层段天然气富集程度从小至大依次为马五1亚段、马五2亚段和马五41小层。     

自然灾害研究中几个观念问题的讨论

本文从人类生活环境系统的整体观角度讨论了自然灾害的两重性、关连性及人类圈之形成和生态环境保护问题。认为自然灾害从短时间尺度和小范围看是灾变, 从长时间尺度和大范围看是一种自调节、自平衡过程;自然灾害与人类社会存在着双向效应关系;自然灾害的关联性(群发共生现象)是由其同源性、链发性和韵律性决定的;人类圈是地球演化进入新阶段的产物, 它具有进行层次深、作用强度高、活动领域宽和通过信息实现调控的特点。建立上述观念, 对灾害研究、减轻灾害损失, 走可持续发展的道路, 都具有重要意义。     

微波等离子体炬质谱技术快速鉴别天然石材与人造石材

天然石材主要有大理石、花岗岩等;人造石材多以不饱和聚酯树脂为基料,添加适量的无机物粉料和添加剂固化制成。由于石材种类繁多,并且各种石材的岩体所含矿物成分也有差异,当前很少应用化学成分分析方法准确、快速鉴别天然和人造石材,仅有的红外光谱法由于对待测物纯度的要求较高而具局限性。本文基于微波等离子体炬源(MPT)同时具有热解吸与强电离能力,能在短时间内离子化待测物的特点,采用微波等离子体炬质谱(MPT-MS)技术,无需样品复杂预处理直接对天然与人造石材进行分析,获得正离子检测模式下在m/z 50~1000之间的石材的指纹谱图,并运用化学计量学的主成分分析(PCA)方法处理所获取的数据,实现了不同建筑石材的区分。结果表明,MPT-MS能够获得石材丰富的指纹谱图,结合PCA方法能够快速鉴别天然石材与人造石材,天然石材中解吸出的物质主要为CO₂和H₂O的团簇分子;而人造石材中解吸出的主要成分为有机物(人为添加的黏合剂等)。本研究采用的MPT-MS技术无需采用喷雾、激光、基质和加热等方法辅助,并且无需对石材进行任何复杂的处理即可进行质谱分析,从而获取石材表面及内部物质的质谱信息,为快速直接鉴定石材样品提供了一种新的质谱分析方法。     

淮南煤田潘三煤矿4-2煤中矿物对岩浆侵入的响应

以淮南煤田潘三煤矿4-2煤层中的岩浆岩、天然焦和煤样品为研究对象,利用X射线衍射仪和X射线荧光光谱仪测试其矿物组成和主量元素含量,研究地下岩浆侵入对煤中矿物成分的影响。结果表明:煤变质成天然焦后,其总的矿物含量增多,并伴随着后生矿物如微斜长石和镁绿泥石的出现。天然焦中后生矿物的组成元素可能来源于岩浆或热液中的主量元素如Si、Al、Na、K、Fe和Mg。     

定向钻穿越技术在清江河天然气管道敷设的应用

清江河天然气管道工程是在河床下穿越1500多米的Φ1016×26.2天然气钢管和Φ114硅管套管。该河为通航河道,河底地面高程最低-5.90m左右,最大水深6.0~8.6m。地层为填土、淤泥质粘粉土、淤泥质粉砂、粉质粘土夹粉砂细砂。施工中通过优化施工方案,针对导向孔轨迹控制、淤泥地层定向钻进纠偏、大口径扩孔清孔和长输大口径管道回拖采取了一些有效的技术措施,确保了工程一次性回拖成功。     

临沂市耕地质量等级状况探析

通过开展耕地质量等级成果补充完善工作,对全面掌握和科学量化耕地质量等级状况,实现国土资源管理部门对耕地的科学化、规范化管理,逐步建立耕地质量等级定期动态调查评价制度、耕地质量等级与产能年度更新报告制度,实现耕地占补平衡由数量管理为主向质量为主、数量为辅的转变,对提升耕地资源保障能力和国土资源管理水平具有重要意义。     

西太暖池区生物组分对海底表层沉积物物理力学性质的影响

西太平洋暖池区是指位于热带西太平洋及印度洋东部海表温度常年在28 ℃以上的海域,是全球海表温度最高的深海区,构造环境与沉积环境复杂,沉积物中的生物组分含量差异较大,生物组分会对深海沉积物物理力学性质产生显著影响,但目前对沉积物中生物组分含量和沉积物物理力学性质之间的相关性关系尚不明确。本文对西太平洋暖池区核心部位的表层沉积物样品进行现场物理力学性质测试和室内涂片鉴定,研究深海表层沉积物的物理力学性质与生物组分之间的关系。结果表明:研究区表层沉积物含水率范围为61.1%~435.1%,天然密度范围为1.04~1.76 g/cm³,贯入阻力范围为0~100 kPa,十字板剪切强度范围为0~8.6 kPa,整体具有高含水率、低密度、低强度等典型的深海沉积物物理力学性质特点。西加洛林海脊、海山等CCD以浅的区域为钙质生物组分>50%的钙质沉积区;西加洛林海槽西南部及其周边的深水沟槽地区一般为硅质生物组分>50%的硅质沉积;西加洛林海盆内部则主要为黏土沉积区。随钙质生物组分减少和硅质生物组分增多,表层沉积物类型分别为钙质沉积物、黏土沉积物和硅质沉积物,天然含水率变高,天然密度、贯入阻力和十字板剪切强度降低,表明深海表层沉积物的物理力学性质与生物组分含量密切相关:贯入阻力、十字板剪切强度、天然密度与钙质生物组分含量呈正相关,与硅质生物组分含量呈负相关;而天然含水率正好相反,与钙质生物组分含量呈负相关,与硅质生物组分含量呈正相关。本文建立了深海沉积物中生物组分与物理力学性质之间的相关关系,提出了沉积物生物组分含量与物理力学性质之间的拟合公式,可以为深海沉积物工程性质的评价提供参考。     

Numerical Simulation Study on the Effect of Horizontal Well Reservoir Stimulation for Gas Hydrate Production

A new gas hydrate reservoir stimulation method of in-situ fracturing with transient heating is proposed, in line with analysis of the technological bottlenecks faced by marine gas hydrate production. This method injects the developed chemical reagents into a hydrate reservoir through hydraulic fracturing, releasing heat during the chemical reaction to increase the hydrate decomposition rate. The chemical reaction product furthermore has a honeycomb structure to support fractures and increase reservoir permeability. Based on the geological model of natural gas hydrate in the South China Sea, three development methods are simulated to evaluate hydrate production capacity, consisting of horizontal well, fractured horizontal well and in-situ fracturing with transient heating well. Compared with the horizontal well, the simulation results show that the cumulative gas production of the fractured horizontal well in one year is 7 times that of the horizontal well, while the cumulative gas production of in-situ fracturing with transient heating well is 12 times that of the horizontal well, which significantly improves daily efficiency and cumulative gas production. In addition, the variation patterns of hydrate saturation and temperature-pressure fields with production time for the three exploitation plans are presented, it being found that three sensitive parameters of fracture conductivity, fracture half-length and fracture number are positively correlated with hydrate production enhancement. Through the simulations, basic data and theoretical support for the optimization of gas hydrate reservoir stimulation scheme has been provided.     

Impact cratering — fundamental process in geoscience and planetary science

Impact cratering is a geological process characterized by ultra-fast strain rates, which generates extreme shock pressure and shock temperature conditions on and just below planetary surfaces. Despite initial skepticism, this catastrophic process has now been widely accepted by geoscientists with respect to its importance in terrestrial — indeed, in planetary — evolution. About 170 impact structures have been discovered on Earth so far, and some more structures are considered to be of possible impact origin. One major extinction event, at the Cretaceous-Paleogene boundary, has been firmly linked with catastrophic impact, but whether other important extinction events in Earth history, including the so-called “Mother of All Mass Extinctions” at the Permian-Triassic boundary, were triggered by huge impact catastrophes is still hotly debated and a subject of ongoing research. There is a beneficial side to impact events as well, as some impact structures worldwide have been shown to contain significant (in some cases, world class) ore deposits, including the gold-uranium province of the Witwatersrand basin in South Africa, the enormous Ni and PGE deposits of the Sudbury structure in Canada, as well as important hydrocarbon resources, especially in North America. Impact cratering is not a process of the past, and it is mandatory to improve knowledge of the past-impact record on Earth to better constrain the probability of such events in the future. In addition, further improvement of our understanding of the physico-chemical and geological processes fundamental to the impact cratering process is required for reliable numerical modeling of the process, and also for the correlation of impact magnitude and environmental effects. Over the last few decades, impact cratering has steadily grown into an integrated discipline comprising most disciplines of the geosciences as well as planetary science, which has created positive spin-offs including the study of paleo-environments and paleo-climatology, or the important issue of life in extreme environments. And yet, in many parts of the world, the impact process is not yet part of the geoscience curriculum, and for this reason, it deserves to be actively promoted not only as a geoscientific discipline in its own right, but also as an important life-science discipline.