软粘土层上的油罐差异沉降

根据某一大型油罐软基加固处理工程方案设计和优选需要,按照离心模型相似律,开展了三组模型试验,分别模拟了天然地基、土工合成材料袋装碎石垫层和既在填土层中设置袋装碎石垫层又在淤泥质粘土层设置土工合成材料排水板三种情况,以研究这一加固布置形式对减小高压缩性软土层地基上油罐罐底的差异沉降效果反应。模型油罐地基采用原型土重塑制备,现场土工合成材料袋装碎石采用柔性机织玻璃纤维细管塞装粗砂条模拟,并在不停机运转条件下模拟了多次充放水预压加载。试验结果表明,油罐软弱地基经土工合成材料袋装碎石加固后,罐底总沉降值和差异沉降值均明显小于天然地基情形下对应的沉降值,罐底畸变得到显著减小,就本文所述的土质条件、土层厚度和预压荷载强度,地基经加固处理后,油罐罐底畸变减小了近50 %。最后就土工合成材料在加固油罐地基布置形式的合理性进行了初步探讨。     

井地直流电法三维数值模拟中若干问题研究

讨论了地下垂直线源分段计算和场叠加的方法,并实现了在套管上供直流电的三维数值模拟。讨论了大型容量矩阵的压缩存储方式,采用数组和结构体相结合的方法实现容量矩阵的一维链表式压缩存储。在求解超大型稀疏线形方程组时引入不完全Cholesky分解稳定化的双共轭梯度算法(ICBG),通过与均匀半空间垂直线源解析解的对比,证明了该算法是准确可靠的。     

青藏铁路清水河段片石护坡路堤温度特性研究

通过对青藏铁路清水河试验段片石护坡、无片石护坡的冻土路堤和地基的温度进行的全面监测,对比分析了路堤体内及基底的地温、积温及温度场中最大融化深度的变化情况,结果表明,采用片石护坡措施的试验路堤,与对比段（普通路堤）相比,降温效果明显。负积温量值大于对比段,最大融化深度抬升幅度较大。因此,片石护坡能够有效发挥降低地温、保护多年冻土的作用,并有利于坡面防护,是一种施作方便,既能用于新建,又能用于补强的多年冻土主动保护措施。     

山东半岛蓝色经济区土壤有机碳储量及固碳潜力分析

土壤碳储量研究在碳循环和全球变化中具有重要意义,但以往碳储量计算结果受到数据来源的制约。山东省多目标区域地球化学调查采用双层网格化采样和分析,获取了大密度、高精度土壤有机碳数据,为土壤碳库的准确计算奠定了基础。笔者利用这些数据计算了山东半岛蓝色经济区表层（0～20 cm）、中上层（0～100 cm）及全层（0～160 cm）的土壤有机碳（SOC）密度和储量,并对其空间分布特征及固碳潜力进行了研究。结果显示,经济区内3种土壤层次的碳库组成不同,表层SOC储量占总碳（TC）储量的71.67%,随深度增加所占比例逐渐减小,而无机碳(SIC)储量所占比例逐渐增加,全层二者所占比率较为接近:表层SOC储量为132.64 Mt,碳密度为2.06 kg/m²;中上层为458.27 Mt,碳密度为7.11 kg/m²;全层为619.96 Mt,碳密度为9.61 kg/m²。各层SOC密度处于全国偏低水平,且在不同土壤类型、地貌类型、土地利用类型之间有一定差异:褐土土表层SOC密度最高（2.48 kg/m²）,风沙土最低（0.91 kg/m²）;灌溉水田表层SOC密度最高（3.45 kg/m²）,菜地最低（1.61 kg/m²）。表层SOC密度分布总体上呈现为沿海地区低、鲁北平原和胶莱盆地中等、山地丘陵和中低山区偏高的分布格局。从第二次土壤普查和本次多目标调查数据所建立的回归方程分析发现,在今后一定时期内,本区表层土壤总体表现为“碳汇”效应,未来可净增总有机碳（TOC）量60.94 Mt,其中“碳源”量5.07 Mt,“碳汇”量65.97 Mt。     

固态存储水位精简摘录的研究

讨论了固态存储水位数据精简摘录存在问题及所需满足的要求。介绍了曲线矢量压缩的Douglas-Peucker算法,对它做了改进并应用于水位过程线的精简摘录。应用实例表明该法能够以精简的数据反应出水位变化完整过程,是使用计算机完成固态存储水位摘录的有效方法。     

CO<Subscript>2</Subscript> Air–Sea Exchange due to Calcium Carbonate and Organic Matter Storage,and its Implications for the Global Carbon Cycle

Release of CO₂ from surface ocean water owing to precipitation of CaCO₃ and the imbalance between biological production of organic matter and its respiration, and their net removal from surface water to sedimentary storage was studied by means of a quotient θ = (CO₂ flux to the atmosphere)/(CaCO₃ precipitated). θ depends not only on water temperature and atmospheric CO₂ concentration but also on the CaCO₃ and organic carbon masses formed. In CO₂ generation by CaCO₃ precipitation, θ varies from a fraction of 0.44 to 0.79, increasing with decreasing temperature (25 to 5°C), increasing atmospheric CO₂ concentration (195–375 ppmv), and increasing CaCO₃ precipitated mass (up to 45% of the initial DIC concentration in surface water). Primary production and net storage of organic carbon counteracts the CO₂ production by carbonate precipitation and it results in lower CO₂ emissions from the surface layer. When atmospheric CO₂ increases due to the ocean-to-atmosphere flux rather than remaining constant, the amount of CO₂ transferred is a non-linear function of the surface layer thickness because of the back-pressure of the rising atmospheric CO₂. For a surface ocean layer approximated by a 50-m-thick euphotic zone that receives input of inorganic and organic carbon from land, the calculated CO₂ flux to the atmosphere is a function of the CaCO₃ and C_org net storage rates. In general, the carbonate storage rate has been greater than that of organic carbon. The CO₂ flux near the Last Glacial Maximum is 17 to 7×10¹² mol/yr (0.2–0.08 Gt C/yr), reflecting the range of organic carbon storage rates in sediments, and for pre-industrial time it is 38–42×10¹² mol/yr (0.46–0.50 Gt C/yr). Within the imbalanced global carbon cycle, our estimates indicate that prior to anthropogenic emissions of CO₂ to the atmosphere the land organic reservoir was gaining carbon and the surface ocean was losing carbon, calcium, and total alkalinity owing to the CaCO₃ storage and consequent emission of CO₂. These results are in agreement with the conclusions of a number of other investigators. As the CO₂ uptake in mineral weathering is a major flux in the global carbon cycle, the CO₂ weathering pathway that originates in the CO₂ produced by remineralization of soil humus rather than by direct uptake from the atmosphere may reduce the relatively large imbalances of the atmosphere and land organic reservoir at 10²–10⁴-year time scales.     

地下盐穴储气库泄漏原因及防治措施研究

良好的密闭性能是盐穴储气库安全运营的基本前提,但地质赋存条件复杂、建库实践不足、理论体系不完备等均会导致盐腔遭遇各类泄漏风险。根据国内外的工程实践及事故统计,再结合盐穴储库特有的工程地质条件和运行工况,总结出三大泄漏因素（地质因素、工程因素、人为失误）和4种泄漏类型。地下盐穴储气库潜在的泄漏类型有夹层密闭性不足引起的气体近水平漏失、盖层被突破失效致使气体上窜、井筒完整性不足致使气体逃逸、夹层与断层连通致使气体流向断层。最终,依据各自的泄漏特征提出了相应的预防处置措施,以防止气体泄漏事故的发生和大范围的蔓延。由于我国盐穴储库的发展暂时处于上升期,研究结果对深部盐穴储气库的安全建设具有一定的借鉴和指导意义。     

山西省地热资源规律及其地质背景研究

中国大陆蕴藏丰富的地热资源,山西省局部地热异常特征明显。通过收集山西省典型地热区域流体数据,选取典型钻孔分析,探讨并总结山西省地热资源赋存规律和成因机制,为后期地热资源勘探及开发利用提供重要参考依据。通过分析研究结果得出以下几点认识：山西省水热型地热储层水温分布在28～78℃,北部以太古代花岗片麻岩为主,中部以古生代灰岩为主,南部以古生代碳酸盐岩为主;北部热源主要来自花岗岩中放射性元素衰变产生热量,中部和南部热源受地幔上隆及岩浆活动影响;省内深大断裂构成地下热水运移通道,热传导性较好;第四纪和第三纪松散层为省内地热良好的保温盖层,岩性以粘土、砂质粘土及砂层为主。结合前人水文地球化学研究成果,认为山西省地热水pH值呈弱碱性,其中Sr、Li、SiO₂与Cl大体上存在正相关关系,大部分地热水氚含量小于1TU,水源主要为大气降水补给,部分地热田出现δ¹⁸O漂移,氧同位素交换作用显著。     

博格达山地区二叠纪以来构造应力场解析及地质意义

博格达山是现代地质学研究的一个热点,但是大部分研究都集中在博格达何时隆升,对于其构造应力场的研究较少。作者通过对博格达山地区不同时代地层中岩墙、节理、褶皱和断层等构造进行分期配套以及构造要素测量分析,认为二叠纪以来博格达山及周缘地区具有较强构造变形,构造应力场可划分为3期:二叠纪末期最大主压应力方向为北西西向,可能与后碰撞伸展作用和乌拉尔碰撞带向东挤压的远程效应有关;侏罗纪末-早白垩世最大主压应力为近南北向,与欧亚板块和拉萨地块的碰撞有关;新近纪以来由于印度板块与欧亚板块相互碰撞的远程效应,博格达山地区最大主应力方向为NNE-NE向。这些结果表明,博格达山具有多期次的构造运动,主要受欧亚板块南缘不同时期小陆块碰撞的控制,并且这些构造应力场对周缘盆地油气成藏具有一定影响。     

Change of Gas Hydrate Reservoir and Its Effect on the Environment in Xisha Trough since the Last Glacial Maximum

In this article, Milkov and Sassen’s model is selected to calculate the thickness of the gas hydrate stable zone (GHSZ) and the amount of gas hydrate in the Xisha (西沙) Trough at present and at the last glacial maximum (LGM), respectively, and the effects of the changes in the bottom water temperature and the sea level on these were also discussed. The average thickness of the GHSZ in Xisha Trough is estimated to be 287 m and 299 m based on the relationship between the GHSZ thickness and the water depth established in this study at present and at LGM, respectively. Then, by assuming that the distributed area of gas hydrates is 8 000 km2 and that the gas hydrate saturation is 1.2% of the sediment volume, the amounts of gas hydrate are estimated to be ~2.76×1010 m3 and ~2.87×1010 m3, and the volumes of hydrate-bound gases are ~4.52×1012 m3 and ~4.71×1012 m3 at present and at LGM, re- spectively. The above results show that the thickness of GHSZ decreases with the bottom water tem- perature increase and increases with the sea level increase, wherein the effect of the former is larger than that of the latter, that the average thickness of GHSZ in Xisha Trough had been reduced by ~12 m, and that 1.9×1011 m3 of methane is released from approximately 1.1×109 m3 of gas hydrate since LGM. The released methane should have greatly affected the environment.