浅层地下水补给对人类活动影响的响应特征研究

本文通过数据整理分析, 查明滹沱河流域平原区1976-2005年以开采量、灌区引水量和河道过水量为代表的人类活动逐渐增强, 分析了浅层地下水补给在大气降水减少和人类活动逐渐增强背景下大幅减少的响应特征: 综合补给量所占比率由1976-1980年的21.6%下降到2000-2005年的11.3%。随后, 从开采量、河道过水量和灌区引水量三个方面分析了浅层地下水补给响应人类活动的变化特征: 地下水补给量与开采量呈y=65.412x-0.2576模式随降水量增减而负相关变化; 河道渗漏补给量和渠水入渗量在地下水位不同埋深条件下表现出随来水量、引水量增加而增大的态势, 但在不同埋深条件下, 河道渗漏补给量与来水量之间、渠水入渗量和引水量之间关系不同。     

南海深海鱼类一新记录种——鞭尾鱼

2016年11月至2020年7月在南海海域采集管眼鱼6尾,经形态特征鉴定为月鱼目、鞭尾鱼科、鞭尾鱼属(Stylephorus)、鞭尾鱼(Stylephorus chordates)。鞭尾鱼主要鉴别特征为：体长,侧扁。眼大,呈望远镜状,朝前或朝上。吻小,管状,口有特别大的伸缩能力。背鳍从颈背部延伸至尾鳍基部。尾鳍分明显的上叶和下叶,下叶2鳍条极度延长。鞭尾鱼在南海海域的发现是该科、该属、该种鱼类在中国海域的首次纪录。     

2011年7月29日山西大暴雨过程的多尺度特征

利用1°×1°的NCEP再分析资料、红外辐射亮温（TBB）、多普勒雷达和气柱水汽总量等资料,对2011年7月28-29日发生在山西境内的区域性暴雨进行多尺度特征分析。结果表明：（1）乌拉尔山阻高崩溃,西风槽东移、副高进退是此次暴雨发生的环流特征;（2）850 hPa低涡切变和700 hPa暖式切变线及地面冷锋是暴雨发生的中α尺度触发系统;（3）〉30 dBZ的雷达回波呈南北向位于地面冷锋与700 hPa切变线之间,雷达回波随地面冷锋和700 hPa切变线的东移而东移;（4）低空低涡切变受500 hPa强盛西南气流的引导向东北移动,暴雨落区始终与低涡切变相伴随;（5）暴雨过程山西境内共有9个中β尺度对流云团活动,山西西南部的暴雨主要由5个中β尺度对流云团的相继移入并在自动站极大风速风场切变线附近触发对流发展所致;山西东南部的大暴雨则是3个中β尺度对流云团合并发展的结果,中γ尺度气旋是导致局地大暴雨发生的直接影响系统;（6）暴雨发生在气柱水汽总量空间分布图中水汽锋的南部和东部及靠近气柱水汽总量的大值区一侧,水汽锋的形成比降水开始提前17 h,比暴雨发生提前24 h以上,对暴雨的短期、短时预报有指示意义。     

始新统油气系统:泰国湾东北部油气勘探新层系

泰国湾区域经历了前裂谷期、裂谷期、裂后期的构造演化阶段,形成了多个裂谷盆地。泰国湾区域东北部在渐新世经历了一次明显构造反转,较泰国湾区域大部分地区强烈。通过对比区内钻井,结合地震解释,对该区的沉积特征和构造演化进行了分析,认为这次反转构造导致了反转构造带上构造、沉积特征与邻区有较大的不同。由于这次反转构造,泰国湾东北部在新层系发育新类型的油气系统,即深部的始新统油气系统:烃源岩为中始新统湖相泥岩,储层为上始新统-渐新统三角洲相砂岩,盖层为下中新统三角洲前缘相泥岩和上中新统以上的海相泥岩。该油气成藏系统已被钻井钻遇油气显示,是本区有效油气成藏系统。     

Organic geochemistry of marine source rocks and pyrobitumen-containing reservoir rocks of the Sichuan Basin and neighbouring areas,SW China

Three bitumen fractions were obtained and systematically analysed for the terpane and sterane composition from 30 Paleozoic source rocks and 64 bitumen-containing reservoir rocks within the Upper Sinian, Lower Cambrian, Lower Silurian, Middle Carboniferous, Upper Permian and Lower Triassic strata in the Sichuan Basin and neighbouring areas, China. These bitumen fractions include extractable oils (bitumen I), oil-bearing fluid inclusions and/or closely associated components with the kerogen or pyrobitumen/mineral matrix, released during kerogen or pyrobitumen isolation and demineralization (bitumen II), and bound compounds within the kerogen or pyrobitumen released by confined pyrolysis (bitumen III). In addition, atomic H/C and O/C ratios and carbon isotopic compositions of kerogen and pyrobitumen from some of the samples were measured. Geochemical results and geological information suggest that: (1) in the Central Sichuan Basin, hydrocarbon gases in reservoirs within the fourth section of the Upper Sinian Dengying Formation were derived from both the Lower Cambrian and Upper Sinian source rocks; and (2) in the Eastern Sichuan Basin, hydrocarbon gases in Middle Carboniferous Huanglong Formation reservoirs were mainly derived from Lower Silurian source rocks, while those in Upper Permian and Lower Triassic reservoirs were mainly derived from both Upper Permian and Lower Silurian marine source rocks. For both the source and reservoir rocks, bitumen III fractions generally show relatively lower maturity near the peak oil generation stage, while the other two bitumen fractions show very high maturities based on terpane and sterane distributions. Tricyclic terpanes evolved from the distribution pattern C₂₀ < C₂₁ < C₂₃, through C₂₀ < C₂₁ > C₂₃, finally to C₂₀ > C₂₁ > C₂₃ during severe thermal stress. The concentration of C₃₀ diahopane in bitumen III (the bound components released from confined pyrolysis) is substantially lower than in the other two bitumen fractions for four terrigenous Upper Permian source rocks, demonstrating that this compound originated from free hopanoid precursors, rather than hopanoids bound to the kerogen.     

Organic geochemistry of the Vindhyan sediments: Implications for hydrocarbons

The organic geochemical methods of hydrocarbon prospecting involve the characterization of sedimentary organic matter in terms of its abundance, source and thermal maturity, which are essential prerequisites for a hydrocarbon source rock. In the present study, evaluation of organic matter in the outcrop shale samples from the Semri and Kaimur Groups of Vindhyan basin was carried out using Rock Eval pyrolysis. Also, the adsorbed low molecular weight hydrocarbons, methane, ethane, propane and butane, were investigated in the near surface soils to infer the generation of hydrocarbons in the Vindhyan basin. The Total Organic Carbon (TOC) content in shales ranges between 0.04% and 1.43%. The S₁ (thermally liberated free hydrocarbons) values range between 0.01–0.09 mgHC/gRock (milligram hydrocarbon per gram of rock sample), whereas the S₂ (hydrocarbons from cracking of kerogen) show the values between 0.01 and 0.14 mgHC/gRock. Based on the T_max (temperature at highest yield of S₂) and the hydrogen index (HI) correlations, the organic matter is characterized by Type III kerogen. The adsorbed soil gas, CH₄ (C₁), C₂H₆ (C₂), C₃H₈ (C₃) and nC₄H₁₀, (nC4), concentrations measured in the soil samples from the eastern part of Vindhyan basin (Son Valley) vary from 0 to 186 ppb, 0 to 4 ppb, 0 to 5 ppb, and 0 to 1 ppb, respectively. The stable carbon isotope values for the desorbed methane (δ¹³C₁) and ethane (δ¹³C₂) range between −45.7‰ to −25.2‰ and −35.3‰ to −20.19‰ (VPDB), respectively suggesting a thermogenic source for these hydrocarbons. High concentrations of thermogenic hydrocarbons are characteristic of areas around Sagar, Narsinghpur, Katni and Satna in the Son Valley. The light hydrocarbon concentrations (C₁–C₄) in near surface soils of the western Vindhyan basin around Chambal Valley have been reported to vary between 1–2547 ppb, 1–558 ppb, 1–181 ppb, 1–37 ppb and 1–32 ppb, respectively with high concentrations around Baran-Jhalawar-Bhanpur-Garot regions (Kumar et al., 2006). The light gaseous hydrocarbon anomalies are coincident with the wrench faults (Kota – Dholpur, Ratlam – Shivpuri, Kannod – Damoh, Son Banspur – Rewa wrench) in the Vindhyan basin, which may provide conducive pathways for the migration of the hydrocarbons towards the near surface soils.     

海拉尔盆地牧原凹陷油气勘探前景与有利区带目标优选

牧原凹陷是海拉尔盆地群中研究程度和勘探程度均较低的凹陷,尚未取得勘探突破。为明确牧原凹陷的油气资源潜力与勘探前景,开展了野外地质调查、老井复查与烃源岩有机地球化学特征研究等,基本明确了凹陷油气地质条件: ①牧原凹陷具有单断箕状结构,可划分为陡坡带、洼槽带和缓坡带3个构造单元; ②发育大磨拐河组、南屯组和兴安岭群3套有效烃源岩,南屯组、大磨拐河组烃源岩厚度大,分布面积广,有机质类型好,以II₁-I型为主,有机质丰度高,生烃潜量大,热演化进入成熟阶段,是凹陷主力烃源岩,兴安岭群烃源岩有机质丰度高,处于高成熟阶段,虽然厚度与分布有限,也是一套有价值的烃源岩; ③发育兴安岭群的自生自储或上生下储、大磨拐河组与南屯组的自生自储、伊敏组的下生上储3套储盖组合。对比高勘探程度区单断箕状凹陷的成藏规律,结合牧原凹陷自身的地质特点,构建了牧原凹陷油气成藏模式。通过开展区带的初步评价,优选出2个有利区带,提出了勘探目标。     

红层“哑地层”划分对比方法——以东营凹陷南坡始新统为例

针对红层划分对比所面临的难题,在充分吸收前人研究成果的基础上,将现有的多种分层方法相互整合,彼此约束和印证,形成了一套科学、便捷的技术方法,即"接触关系明顶底、岩电特征找界面、多元融合定方案、地震约束建格架"的综合地层划分对比技术。该方法针对红层的特殊性,根据岩电特征对干旱气候的响应变化,充分利用了测、录井资料纵向上的连续性优势(避免了取样分析的局限),以及地震资料横向上的优势,有效地解决了红层纵向划分、横向对比的难题,在济阳坳陷东营凹陷南坡始新统沙河街组、孔店组的应用取得了良好效果。该方法可为其它地区同类复杂地层划分对比提供技术支持。     

乌鲁木齐冬季黑碳气溶胶污染特征初步研究

利用2010年2月乌鲁木齐大气成分观测站黒碳仪观测数据,结合散射系数及常规观测资料,对乌鲁木齐冬季黑碳气溶胶浓度变化特征进行了分析,并通过气流后向轨迹进行了来源分析。结果表明：(1)观测期间BC质量浓度日平均值为12707±4673 ng.m-3,浓度变化范围为4916~22997 ng.m-3,散射系数日均值为1086±561Mm-1,变化范围为350~2232 Mm-1。BC质量浓度和散射系数日均值变化趋势基本一致;(2)BC质量浓度日变化具有明显的峰值和谷值,峰值分别出现在9~11时和20~22时,谷值分别出现在4~6时和16~18时,散射系数与BC质量浓度日变化趋势基本一致,相对其有一定的滞后。春节期间燃放烟花爆竹对空气污染物浓度上升有明显作用,显著影响BC质量浓度日变化规律;(3)乌鲁木齐冬季大气层结稳定,污染物不易扩散,风速和降水对黑碳气溶胶浓度具有明显的稀释作用。在乌鲁木齐特殊的地形和气象条件下,本地源排放与来自周边城市群污染物输送的叠加使得污染更加严重。     

用传输矩阵方法研究多层介质增透膜的透射特性

利用麦克斯韦方程组和边界条件,推导出由高低折射率介质组成周期性的多层增透膜系的传输矩阵,用传输性矩阵求出增透膜系的反射率和透射率表示式,采用Maple语言和数值计算方法得到4层和8层高反射膜系的反射率随入射光波长变化曲线,分析和讨论入射光的入射角对反射率和透射率的影响.得到的结果有利于对多层介质增透膜系结构的理解,为光学仪器镀膜的设计提供了理论依据.