MT有限元模拟中截断边界的影响

利用有限元方法进行大地电磁正演数值模拟时,由于是在有限网格区域上的数值计算,模拟计算时的网格边界为截断边界,而有限元数值模拟时的大地电磁场边界条件需要在足够远处才能够满足,所以截断边界的存在可能会使大地电磁正演模拟的边界条件无法满足,致使对计算结果和计算精度产生影响。利用有限元二维正演程序,在网格边界处加载一维情况下的大地电磁场,然后固定研究区域的网格剖分,并对一维地电模型和二维地电模型在改变有限元网格边界大小的情况下进行计算。在对一维模型进行模拟计算时,截断边界对边界条件没有影响,边界条件自然满足。而对二维模型进行模拟计算时,截断边界的存在对计算结果有较大影响。利用趋肤深度作为有限元网格边界变化的量度,通过改变网格边界大小,对不同的二维地电模型进行计算比较,总结出适合大地电磁有限元正演模拟的参考网格边界。     

高土石坝裂缝分析的变形倾度有限元法及其应用

土石坝张拉裂缝一般由坝体的不均匀沉降变形引起,是土石坝破坏的主要诱因和表现形式之一。将基于现场沉降监测资料的传统变形倾度法进行了扩展,通过在有限元计算程序中嵌入变形倾度计算模块,发展了基于有限元变形计算的变形倾度有限元法。该方法简洁实用,方便与常规有限元变形计算相耦合,可作为在工程设计阶段分析和估算土石坝是否会发生表面张拉裂缝的实用方法。应用所发展的变形倾度有限元法,以糯扎渡高心墙堆石坝工程为例,进行了坝体后期变形引起坝体表面发生张拉裂缝的敏感性计算分析,探讨了高土石坝变形倾度的分布规律以及与坝体后期变形的关系,发现对糯扎渡高心墙堆石坝,坝顶后期沉降最大值小于坝高0.39%,可作为防止发生坝顶横向张拉裂缝的控制工况。通过工程实例的计算,说明提出的方法可用于高土石坝的裂缝预测分析。     

源外斜坡区有利于油气运聚的断砂配置分布区预测方法

为了研究含油气盆地源外斜坡区油气分布规律,在源外斜坡区断砂配置运聚机制及有利分布区研究的基础上,通过砂体连通分布区和砂体所在地层顶面砂体输导油气汇聚区,确定油气成藏期砂体输导油气分布区;通过断裂填充物泥质含量与断裂侧向封闭所需的最小填充物泥质含量的相对大小,确定油气成藏期河道砂体上倾方向断裂侧向封闭部位,二者叠合建立了一套源外斜坡区有利于油气运聚的断砂配置分布区预测方法,并将其应用于渤海湾盆地歧口凹陷有利于油气运聚的扣村断裂与沙一下亚段砂体配置分布区的预测中。结果表明：有利于油气运聚的扣村断裂与沙一下亚段砂体配置分布区主要分布在其东部,有利于西北歧南次凹沙三段源岩生成油气在扣村断裂附近沙一下亚段内聚集成藏,与目前扣村断裂附近沙一下亚段已发现油气主要分布在其东部相吻合,表明该方法用于预测源外斜坡区有利于油气运聚的断砂配置分布区是可行的。     

基于熵值法和突变级数法的泥石流易损度评价

泥石流易损度（危害性）评价是泥石流风险评估的重要组成部分.结合熵值法和突变理论的泥石流易损度评价方法，采用客观的熵值法判断指标间相对重要程度，利用突变级数法计算突变级数值进行评价，方法理论基础牢固且避免了确定指标权重值的弊端.以吉林省和龙市地质灾害调查与区划中的10条泥石流易损度评价实例进行验证，结果表明：数据获取、标准化和评价过程简便，易损度等级以轻度和中度为主的评价结果符合实际情况，该方法经过完善指标体系后可更加合理地应用于实际工作中.因此，基于熵值法和突变理论的泥石流易损度评价方法是可行的、可靠的.     

软土地基沉降计算的误差分析

对引起路堤荷载下软土地基沉降从竖应力、固结沉降、瞬时沉降和后期沉降的计算四个方面,常见计算方法误差的诸多因素,从受力、沉降原理上进行了详细分析并提出一些建议,以使沉降更为接近实际.     

金刚石工具富铁胎体掺杂稀土的研究

稀土的加入量、加入形态和在混料中的均匀弥散性直接影响热压富铁金刚石复合材料的性能。改进的稀土掺杂工艺，保证了稀土在胎体中的均匀弥散性；通过试验研究了稀土的加入量与富铁胎体的抗弯强度、抗冲击韧性和孔隙率的关系，从而确定了稀土的最优加入量。通过差热分析试验，认为稀土可以改变富铁胎体的热物理特性。     

桩体复合地基桩、土相互作用的解析法

桩体复合地基的设计中,承载力及沉降的计算一直没有较好地考虑桩、土和垫层的相互作用。根据三者的协同作用,推导出大面积群桩中桩、土的荷载传递基本微分方程并给出其解答。该方法提高了计算速度,土性参数均为常规指标,简便易得。该方法还考虑了桩侧阻随侧向土压力的变化以及垫层、土体压缩模量随压力的变化。与有限元计算结果对比表明了该解答的可行性。能够对桩土分担比以及沉降的计算提供帮助,是一种简便实用的方法。     

Differential subduction and exhumation of crustal slices in the Sulu HP-UHP metamorphic terrane: insights from mineral inclusions, trace elements, U-Pb and Lu-Hf isotope analyses of zircon in orthogneiss

Based on new evidence the Sulu orogen is divided from south‐east to north‐west into high‐pressure (HP) crustal slice I and ultrahigh‐pressure (UHP) crustal slices II and III. A combined set of mineral inclusions, cathodoluminescence images, U‐Pb SHRIMP dating and in situ trace element and Lu‐Hf isotope analyses was obtained on zircon from orthogneisses of the different slices. Zircon grains typically have three distinct domains that formed during crystallization of the magmatic protolith, HP or UHP metamorphism and late‐amphibolite facies retrogression, respectively: (i) oscillatory zoned cores, with low‐pressure (LP) mineral inclusions and Th/U > 0.38; (ii) high‐luminescent mantles (Th/U < 0.10), with HP mineral inclusions of Qtz + Grt + Arg + Phe + Ap for slice I zircon and Coe + Grt + Phe + Kfs + Ap for both slices II and III zircon; (iii) low‐luminescent rims, with LP mineral inclusions and Th/U < 0.08. Zircon U‐Pb SHRIMP analyses of inherited cores point to protolith ages of 785–770 Ma in all seven orthogneisses. The ages recorded for UHP metamorphism and subsequent retrogression in slice II zircon (c. 228 and c. 215 Ma, respectively) are significantly older than those of slice III zircon (c. 218 and c. 202 Ma, respectively), while slice I zircon recorded even older ages for HP metamorphism and subsequent retrogression (c. 245 and c. 231 Ma, respectively). Moreover, Ar‐Ar biotite ages from six paragneisses, interpreted as dating amphibolite facies retrogression, gradually decrease from HP slice I (c. 232 Ma) to UHP slice II (c. 215 Ma) and UHP slice III (c. 203 Ma). The combined data set suggests decreasing ages for HP or UHP metamorphism and late retrogression in the Sulu orogen from south‐east to north‐west. Thus, the HP‐UHP units are interpreted to represent three crustal slices, which underwent different subduction and exhumation histories. Slice I was detached from the continental lithosphere at ～55–65 km depth and subsequently exhumed while subduction of the underlying slice II continued to ～100–120 km depth (UHP) before detachment and exhumation. Slice III experienced a similar geodynamic evolution as slice II, however, both UHP metamorphism and subsequent exhumation took place c. 10 Myr later. Magmatic zircon cores from two types of orthogneiss in UHP slices II and III show similar mid‐Neoproterozoic crystallization ages, but have contrasting Hf isotope compositions (εHf_(～785) = ?2.7 to +2.2 and ?17.3 to ?11.1, respectively), suggesting their formation from distinct crustal units (Mesoproterozoic and Paleoproterozoic to Archean, respectively) during the breakup of Rodinia. The UHP and the retrograde zircon domains are characterized by lower Th/U and ¹⁷⁶Lu/¹⁷⁷Hf but higher ¹⁷⁶Hf/¹⁷⁷Hf(t) than the Neoproterozoic igneous cores. The similarity between UHP and retrograde domains indicates that late retrogression did not significantly modify chemical and isotopic composition of the UHP metamorphic system.