宁波某厂房室内地坪沉降原因分析及处理措施

针对宁波市宁海县宁东区块某厂房室内地坪沉降现象,在分析沉降原因和沉降趋势的基础上,结合本工程的具体条件对几种加固方法进行了对比,确定采用锚杆桩 梁板结构加固方式对地坪进行处理。研制了多功能小型静力压桩机、采用了小创面多级挤扩贯穿排障法等解决了施工中的难题,实现了复杂环境条件的特种专业工程的顺利施工。治理效果良好。     

冈底斯带南部桑日高分异I型花岗岩的岩石成因及其动力学意义

冈底斯岩浆岩带位于西藏南部的拉萨地体南缘,它形成于特提斯洋和印度-亚洲大陆长期俯冲碰撞过程中,是青藏高原花岗岩最发育的地区。前人对冈底斯岩浆带中各类型花岗岩的成因、源区、时空分布以及其地球动力学意义进行了详细大量的研究,但是对高分异花岗岩的具体成因、演化过程以及在70~65Ma拉萨地块的地球动力学演化过程研究较少。本文选择冈底斯南缘白垩纪末桑日花岗岩进行研究,揭示了桑日花岗岩的岩石学特征、锆石U-Pb年龄、锆石Hf同位素特征和地球化学特征。本文样品LA-ICP-MS测得的锆石U-Pb年龄为67~66Ma。桑日花岗岩属于高钾钙碱性系列,具有高Si O2(74.26%~76.93%)、高K2O+Na2O(7.87%~8.56%),低P2O5(0.02%~0.04%)和Ca O(0.28%~1.00%),以及富集K、Rb、Th,亏损Nb、P、Ti的高分异I型花岗岩的特征。在锆石Hf同位素上,桑日花岗岩εHf(t)0(+4.6~+10.9),且具有Hf不均一的特征。结合前人研究,本文认为桑日花岗岩是高分异I型花岗岩,在特提斯洋板块北向俯冲过程中,板片回转,俯冲洋壳脱水产生的流体进入地幔楔,引发地幔楔发生部分熔融产生镁铁质幔源物质并底侵上涌,导致浅部地壳发生部分熔融,并与幔源岩浆混合,从而在浅部形成混源岩浆房,最终在侵位与成岩后期经历高程度的分异演化形成的。     

Mantle discontinuities beneath Izu-Bonin and the implications

The detailed structure of the Earths interior is a major field of geophysics study and the existence and the properties of mantle discontinuities are its important content. Since the lateral heterogeneity was discovered with the seismic tomography method,…     

日本南海海槽地震区域应力场及其板块构造动力学特征

为了研究海沟型巨大地震发生机制及其构造动力学特征，详细研究了地震活动与震源机制结果，根据地震俯冲带几何形状及其内应力场区域特征，南海海槽下的俯冲带可划分为两段: 东部的四国-纪伊半岛段和西部的九州段. 东部的菲律宾海板块地震俯冲带呈现出低角度俯冲(10°～22°)，且俯冲深度相当浅(60～85km)的特征;而西部九州段的俯冲带为高角度俯冲(40°)，且俯冲深度较深(160km). 东、西部俯冲带内部应力场也截然不同. 东部的四国大部分地区和纪伊半岛的俯冲带内表现为俯冲压缩型应力场， 而西部的九州段则为明显的俯冲拉张型应力场. 本文在综合分析了重力异常、GPS、热流量等地球物理观测结果后指出，南海海槽东部， 即四国-纪伊半岛以南的海槽区域， 具有与智利海沟极其相似的地震发生板块构造动力学背景和高应力积累等特征， 属于年轻活动俯冲带的高应力型俯冲. 而西部的九州段，虽然也是海沟型地震活动区， 但不具有大地震发生的构造动力学背景和高应力积累， 不属于年轻活动俯冲带的高应力型俯冲. 俯冲带年龄的不同很可能是造成南海海槽东、西段板块构造动力学以及应力场不同的根本原因之一.     

Geochemistry of Adakites from the Philippines: Constraints on Their Origins

Abstract. We have identified in the Philippine Archipelago 230 samples of Late Miocene to Quaternary intermediate and evolved magmatic rocks or glasses, the compositions of which plot within the adakitic field defined by Defant and Drum-mond (1990) using Sr/Y ratios versus Y contents. These rocks belong to four different subductions, along the Manila Trench (Batan, Northern Luzon, Central Luzon), the Negros and Sulu Trenches (Negros and Western Mindano), the Cotobato Trench (Southern Mindanao) and the Philippine Trench (Eastern Mindanao). Lavas from Central Mindanao overlie the deep remnants of the Molucca Sea Plate, and were emplaced in a post-collision setting.
All these samples show a significant depletion in Y and HREE with respect to their "normal" calc-alkaline equivalents, suggesting that garnet was either a residual phase during partial melting or a fractionating mineral during differentiation or assimilation coupled with fractional crystallisation (AFC). However, only 19 samples out of our set (i.e., 8 %) display very high Sr/Y ratios (100–250). Our preferred model for the genesis of these "typical adakites" is ca. 20 % partial melting of subducted altered oceanic metabasalts converted to eclogite. This melting process could have been triggered by water from the underlying serpentinites. Most of the samples, termed "intermediate adakites", display major and trace element chemical features intermediate between those of the former group and those of normal calc-alkaline lavas. We show that magma mixing between slab-derived adakitic magmas and mafic mantle-derived melts accounts for most of the trends linking typical and intermediate adakites, although an additional contribution of mantle is required in some cases.     

云母复合材料板的合成研制

选择了云母作为纤维矿物材料替换石棉，填料选用叶蜡石、方解石和方镁石等矿物，进行云母复合材料板合成，并详细解析分别由云母、云母 方解石、云母 叶蜡石 方解石、云母 方解石 叶蜡石 方镁石等一元、二元、三元和四元等材料合成的复合材料板的物理性质和机械性能，得出了以多元矿物材料合成的制品的质量优于单元矿物材料合成的制品，以四元矿物材料合成的云母复合材料板可任意切割，复合材料的厚度可达到5mm左右。     

Geology and geochemistry of Karasugasen lava dome, Daisen–Hiruzen Volcano Group, southwest Japan

Abstract   The geology and geochemistry of pyroclastic flows and fallout tephras formed during the Karasugasen dome eruption in the Daisen–Hiruzen Volcano Group in southwest Japan have been examined in detail. The Karasugasen lava dome erupted at about 26 ka. The eruption began with a vulcanian ash fall, and this was followed by at least eight block and ash flows and a pumice flow. The block and ash flows were produced by the successive collapses of a growing lava dome. This main eruption phase was followed by an eruption of vulcanian ash falls, and finally ended with a sub-Plinian pumice fall. This eruption sequence is typical of the Daisen Volcano during the last three eruption events, which occurred at 58, 26 and 17 ka. The magma produced during the Karasugasen eruption was a typical adakite, with extremely high Sr/Y ratios and low HREE/LREE ratios compared to normal arc lavas. The chemistry of the Karasugasen lavas is almost identical to other Daisen–Hiruzen lavas that were produced from eruptions over an interval of a million years. The continuous supply of a huge amount of adakitic magma (>100 km³) for such a long period suggests a massive homogeneous source material, such as molten Philippine Sea Plate slab. Slab melting is a plausible mechanism for the production of the adakitic lavas at Karasugasen, and hence the Daisen–Hiruzen Volcano Group.