利用地震相识别优质烃源岩--以辽中凹陷沙三段为例

利用地震资料,在沙三段精细层位标定的基础上,进行辽中凹陷沙三段地震地层的追踪解释。根据优质烃源岩的定义及判识标准,即主要为一套富含有机质的中深湖相暗色泥岩沉积,识别出优质烃源岩地震相主要呈低频、连续、强反射特征。在地震相和沉积相分析的基础上,建立了辽中凹陷三个次洼优质烃源岩地震相-沉积相模式,并对辽中凹陷沙三段优质烃源岩进行了分布预测,研究表明辽中凹陷沙三段优质烃源岩在北洼分布范围较大,中洼次之,南洼分布最小;在辽中北洼,整个沙三段均有分布;在辽中凹陷中洼,优质烃源岩发育于沙三中亚段;在辽中凹陷南洼,主要发育于沙三段下部。     

松散岩土体在不同浸泡环境中阴离子浸出特征试验研究

三峡库区大型的赵树岭滑坡区滑坡灾害极为发育。三峡工程蓄水后,水位上升导致原先许多非饱水的松散岩土体处于饱水状态,严重破坏了其稳定性。文章针对该滑坡区内广泛分布的松散岩土的基本类型和特点,设计了4种不同的浸泡环境,进行水-松散岩土相互作用的室内控制试验,通过监测阴离子浸出特征来揭示其化学变化规律。试验结果表明:在不同的pH值、不同的搅拌速度、不同的流速、以及同时改变pH值和搅拌速度的试验环境中,水岩化学作用所浸出的阴离子特征各异。研究结果可以为松散岩土-水化学作用机理研究提供资料,也对赵树岭滑坡体的工程治理具有重要指导意义。     

新疆罗布泊盐湖氢氧锶硫同位素地球化学及钾矿成矿物质来源

罗布泊罗北凹地第四系上部盐层中蕴藏丰富的卤水,卤水中则富含钾（ＫＣｌ平均品位为１．４０％）。文章通过对罗布泊卤水氢、氧、锶及硫同位素等分析及与塔里木盆地（河流）、柴达木盆地等地区对比研究,确定了罗布泊富钾卤水源于地表水,可能主要是塔里木盆地南北缘河流水;卤水中的硫钾等物质组分主要来源于南天山、塔里木盆地西北、西南部中新生代石膏钙芒硝石盐矿床或地层及其古代地层卤水。由于第四纪期间塔里木盆地西部抬升。     

改性氢氧化镁对地下水中铅镉的稳定化性能研究

为研究OH-缓释剂对铅、镉污染地下水修复的可行性,通过室内实验制备改性氢氧化镁,并对其去除地下水中Pb和Cd的性能进行研究。实验结果表明,重金属的稳定化机理主要为沉淀反应。在去除单一重金属(Pb或Cd)实验中,Pb和Cd的去除率都可达到99%以上,反应符合一级反应动力学,反应速率常数分别为0.173 7 min-1和0.003 7 min-1。改性氢氧化镁在处理Pb和Cd的复合污染时Pb优先于Cd反应,Pb的存在会对Cd的沉淀起到抑制作用。     

东海陆架盆地南部中生界沉积模式

在沉积相综合分析基础之上,通过地震相分析的手段明确了东海陆架盆地南部中生界的沉积特征;结合古地理背景分析,建立了该区侏罗纪和白垩纪的沉积模式。侏罗纪时雁荡低凸起和瓯江凹陷均未形成,闽江凹陷和基隆凹陷连为一体,物源来自浙闽隆起区,发育滨浅海沉积体系,火山作用较为强烈。白垩纪晚期-古新世,随着太平洋板块俯冲角度的加大,浙闽隆起区发生裂陷,雁荡低凸起形成。西部的瓯江凹陷沉积了一套陆相的冲积扇-河流-三角洲-湖泊沉积体系;由于此间台北低凸起尚未起到分割作用,东部的闽江凹陷与基隆凹陷仍然连为一体,物源来自浙闽隆起带和台北水下火山岩带,发育滨浅海沉积体系,火山作用影响强烈。     

CMPA降水资料在中国地区不同地形下的精度评价研究

以2001—2010年中国地面自动站降水资料为基准,对中国大陆范围内CMPA(CMPA_Daily)降水资料进行精度评价研究,并与CMORPH1.0(CPC MORPHing technique gauge-satellite)、TRMM3B43V7(Tropical Rainfall Measuring Mission 3B43)降水资料精度进行对比,并进一步结合高程、坡度、坡向、坡向修正因子分析地形因子对数据质量的影响并探讨不同地貌类型下数据的精度。结果显示:CMPA在年、月尺度上均能较好地反映降水的多寡,与站点实测数据具有较高的相关性,误差波动较为平稳,数据质量及稳定性优于CMORPH与TRMM;从时间序列曲线显示CMPA的精度呈现较为明显的季节性差异,均方根误差夏季高于冬季,相关系数、百分比偏差、平均相对误差冬季高于夏季,总体而言CMPA夏季的误差高于冬季,由于夏季降水的基数大而导致了百分比偏差以及平均相对误差较低;分析地形的影响表明,高程、坡度对数据质量的影响大于坡向与坡向修正因子;在复杂地形下,高海拔与高坡度地区CMPA精度均有所降低,但降水资料的精度仍然优于CMORPH与TRMM。     

不同河岸植物带对非点源污染河水污染物降解的试验研究

利用2种植物带(芦苇、香蒲与芦苇)对受非点源污染河水进行植物带处理污染物的降解效果模拟试验研究。结果表明,植物带处理污染物的降解效果明显优于无植物带,且以混合植物带效果最好。香蒲与芦苇植物带对COD、TN、TP和NH3-N去除率的周平均值分别为31.62%、37.84%、30.65%和34.31%。植物带能够截留地表径流中的颗粒物,提高水域中的溶解氧含量,对防止水土流失与改善流域水质均有显著作用。     

夏季西北干旱气候形成的数值模拟——高原地形和环流场等的影响

为了进一步检验和修改本文部分作者先前初步提出的影响夏季西北干旱气候形成的因子及如何相互作用形成西北干旱气候的物理图像,本文继续用一全球大气环流谱模式,设计了5组试验,利用ECMWF 的格点分析值资料,进行了数值模拟。结果表明,青藏高原隆升和环流差异是形成西北干旱气候的重要因子,已提出的西北干旱气候形成的物理图像大体是正确的。     

Carbon pools and fluxes in the China Seas and adjacent oceans

The China Seas include the South China Sea, East China Sea, Yellow Sea, and Bohai Sea. Located off the Northwestern Pacific margin, covering 4700000 km~2 from tropical to northern temperate zones, and including a variety of continental margins/basins and depths, the China Seas provide typical cases for carbon budget studies. The South China Sea being a deep basin and part of the Western Pacific Warm Pool is characterized by oceanic features; the East China Sea with a wide continental shelf, enormous terrestrial discharges and open margins to the West Pacific, is featured by strong cross-shelf materials transport; the Yellow Sea is featured by the confluence of cold and warm waters; and the Bohai Sea is a shallow semiclosed gulf with strong impacts of human activities. Three large rivers, the Yangtze River, Yellow River, and Pearl River, flow into the East China Sea, the Bohai Sea, and the South China Sea, respectively. The Kuroshio Current at the outer margin of the Chinese continental shelf is one of the two major western boundary currents of the world oceans and its strength and position directly affect the regional climate of China. These characteristics make the China Seas a typical case of marginal seas to study carbon storage and fluxes. This paper systematically analyzes the literature data on the carbon pools and fluxes of the Bohai Sea,Yellow Sea, East China Sea, and South China Sea, including different interfaces(land-sea, sea-air, sediment-water, and marginal sea-open ocean) and different ecosystems(mangroves, wetland, seagrass beds, macroalgae mariculture, coral reefs, euphotic zones, and water column). Among the four seas, the Bohai Sea and South China Sea are acting as CO_2 sources, releasing about0.22 and 13.86–33.60 Tg C yr~(-1) into the atmosphere, respectively, whereas the Yellow Sea and East China Sea are acting as carbon sinks, absorbing about 1.15 and 6.92–23.30 Tg C yr~(-1) of atmospheric CO_2, respectively. Overall, if only the CO_2 exchange at the sea-air interface is considered, the Chinese marginal seas appear to be a source of atmospheric CO_2, with a net release of 6.01–9.33 Tg C yr~(-1), mainly from the inputs of rivers and adjacent oceans. The riverine dissolved inorganic carbon (DIC) input into the Bohai Sea and Yellow Sea, East China Sea, and South China Sea are 5.04, 14.60, and 40.14 Tg C yr~(-1),respectively. The DIC input from adjacent oceans is as high as 144.81 Tg C yr~(-1), significantly exceeding the carbon released from the seas to the atmosphere. In terms of output, the depositional fluxes of organic carbon in the Bohai Sea, Yellow Sea, East China Sea, and South China Sea are 2.00, 3.60, 7.40, and 5.92 Tg C yr~(-1), respectively. The fluxes of organic carbon from the East China Sea and South China Sea to the adjacent oceans are 15.25–36.70 and 43.93 Tg C yr~(-1), respectively. The annual carbon storage of mangroves, wetlands, and seagrass in Chinese coastal waters is 0.36–1.75 Tg C yr~(-1), with a dissolved organic carbon(DOC) output from seagrass beds of up to 0.59 Tg C yr~(-1). Removable organic carbon flux by Chinese macroalgae mariculture account for 0.68 Tg C yr~(-1) and the associated POC depositional and DOC releasing fluxes are 0.14 and 0.82 Tg C yr~(-1), respectively. Thus, in total, the annual output of organic carbon, which is mainly DOC, in the China Seas is 81.72–104.56 Tg C yr~(-1). The DOC efflux from the East China Sea to the adjacent oceans is 15.00–35.00 Tg C yr~(-1). The DOC efflux from the South China Sea is 31.39 Tg C yr~(-1). Although the marginal China Seas seem to be a source of atmospheric CO_2 based on the CO_2 flux at the sea-air interface, the combined effects of the riverine input in the area, oceanic input, depositional export,and microbial carbon pump(DOC conversion and output) indicate that the China Seas represent an important carbon storage area.     

地震前兆复杂性成因机理研究的讨论（二）：地震前兆复杂性成因机理

针对前兆复杂性的种种表现,作从震源、构造应力场、断裂力学、前兆监测等方面探讨了前兆复杂性产生的可能原因。认为前兆复杂性是客观存在的,与共性一起构成前兆的二重性,因此在研究前兆时,既要研究共性,也要研究复杂性,才能更好地掌握或认识前兆。同时从复杂性中再寻求普遍性,进一步完善孕震理论和开发新的分析预报方法;造成前兆复杂性的根本原因是孕震的物理力学过程的复杂性,其中包括地质构造、孕震环境、动力学过程、