Diopside and Magnetite Exsolutions in Olivine from Lower Cr# Dunite in the Dongbo Ophiolite, Southern Tibet

<正>Diopside and magnetite exsolutions occur as oriented intergrowths within olivine of the lower Cr~#dunite in the Dongbo ophiolite,Tibet.The fresh lower Cr~#dunite has a mineral assemblage of olivine,spinel and diopside.The Fo content of its olivine is 90–92,which is lower than that of the higher Cr~#dunite lenses(Fo92-Fo94)without     

Diamond in Oceanic Peridotites and Chromitites: Evidence for Deep Recycled Mantle in the Global Ophiolite Record

Diamonds have been discovered in mantle peridotites and chromitites of six ophiolitic massifs along the 1300 km‐long Yarlung‐Zangbo suture (Bai et al., 1993; Yang et al., 2014; Xu et al., 2015), and in the Dongqiao and Dingqing mantle peridotites of the Bangong‐Nujiang suture in the eastern Tethyan zone (Robinson et al., 2004; Xiong et al., 2018). Recently, in‐situ diamond, coesite and other UHP mineral have also been reported in the Nidar ophiolite of the western Yarlung‐Zangbo suture (Das et al., 2015, 2017). The above‐mentioned diamond‐bearing ophiolites represent remnants of the eastern Mesozoic Tethyan oceanic lithosphere. New publications show that diamonds also occur in chromitites in the Pozanti‐Karsanti ophiolite of Turkey, and in the Mirdita ophiolite of Albania in the western Tethyan zone (Lian et al., 2017; Xiong et al., 2017; Wu et al., 2018). Similar diamonds and associated minerals have also reported from Paleozoic ophiolitic chromitites of Central Asian Orogenic Belt of China and the Ray‐Iz ophiolite in the Polar Urals, Russia (Yang et al., 2015a, b; Tian et al., 2015; Huang et al, 2015). Importantly, in‐situ diamonds have been recovered in chromitites of both the Luobusa ophiolite in Tbet and the Ray‐Iz ophiolite in Russia (Yang et al., 2014, 2015a). The extensive occurrences of such ultra‐high pressure (UHP) minerals in many ophiolites suggest formation by similar geological events in different oceans and orogenic belts of different ages. Compared to diamonds from kimberlites and UHP metamorphic belts, micro‐diamonds from ophiolites present a new occurrence of diamond that requires significantly different physical and chemical conditions of formation in Earth's mantle. The forms of chromite and qingsongites (BN) indicate that ophiolitic chromitite may form at depths of >150‐380 km or even deeper in the mantle (Yang et al., 2007; Dobrthinetskaya et al., 2009). The very light C isotope composition (δ13C ‐18 to ‐28‰) of these ophiolitic diamonds and their Mn‐bearing mineral inclusions, as well as coesite and clinopyroxene lamallae in chromite grains all indicate recycling of ancient continental or oceanic crustal materials into the deep mantle (>300 km) or down to the mantle transition zone via subduction (Yang et al., 2014, 2015a; Robinson et al., 2015; Moe et al., 2018). These new observations and new data strongly suggest that micro‐diamonds and their host podiform chromitite may have formed near the transition zone in the deep mantle, and that they were then transported upward into shallow mantle depths by convection processes. The in‐situ occurrence of micro‐diamonds has been well‐demonstrated by different groups of international researchers, along with other UHP minerals in podiform chromitites and ophiolitic peridotites clearly indicate their deep mantle origin and effectively address questions of possible contamination during sample processing and analytical work. The widespread occurrence of ophiolite‐hosted diamonds and associated UHP mineral groups suggests that they may be a common feature of in‐situ oceanic mantle. The fundamental scientific question to address here is how and where these micro‐diamonds and UHP minerals first crystallized, how they were incorporated into ophiolitic chromitites and peridotites and how they were preserved during transport to the surface. Thus, diamonds and UHP minerals in ophiolites have raised new scientific problems and opened a new window for geologists to study recycling from crust to deep mantle and back to the surface.     

Multi‐stage Melting Processes of Ophiolitic Chromitites from Purang Peridotite,the Western Yarlung‐Zangbo Suture Zone,Tibet

The Purang ophiolite, which crops out over an area of about 600 km2 in the western Yarlung‐Zangbo suture zone, consists chiefly of mantle peridotite, pyroxenite and gabbro. The mantle peridotites are mostly harzburgite and minor lherzolite that locally host small pods of dunite. Some pyroxenite and gabbro veins of variable size occur in the peridotites, and most of them strike NW. On the basis of their mineral chemistry podiform chromitites are divided into high‐alumina (Cr# = 20‐60) (Cr# = 100*Cr/(Cr+Al)) and high‐chromium (Cr# = 60‐80) varieties (Thayer, 1970). Typically, only one type occurs in a given peridotite massif, although some ophiolites contain several massifs which can have different chromitite compositions. However, the Purang massif contains both high chrome and high alumina chromitites within a single mafic‐ultramafic body. Seven small, lenticular bodies of chromitite ore have been found in the harzburgite, with ore textures ranging from massive to disseminated to sparsely disseminated; no nodular ore has been observed. Individual ore bodies are 2‐6 m long, 0.5‐2 m wide and strike NW, parallel to the main structure of the ophiolite. Ore bodies 1 and 6 consist of Al‐rich chromitite (Cr# = 52‐55), whereas orebodies 2, 3, 4 and 5 are Cr‐rich varieties (Cr # = 63 to 89). In addition to magnesiochromite, all of the orebodies contain minor olivine, amphibole and serpentine. Mineral structures show that the peridotites experienced plastic deformation and partial melting. On the basis of magnesiochromite and olivine/clinopyroxene compositions two stages of partial melting are identified in the Purang peridotites, an early low‐partial melting event (about 8%), and a later high‐partial melting event (about 40%). We interpret the Al‐rich chromitites as the products of early MORB magmas, whereas the Cr‐rich varieties are thought to have been generated by the later SSZ melts..     

基于时空影响因子的未来社区生活圈公共服务设施优化配置北大核心CSCD

公共服务设施作为社区生活圈的核心内容,直接决定了社区生活圈的生活品质。对社区公共服务设施建设情况进行量化评价,并对设施建设的未来规划提供科学决策支持逐渐成为规划者和决策者的一大难题。本文通过ArcGIS工具对POI数据进行处理、统计和可视化,在总结他人社区生活圈量化评价方法的基础上,结合温州本地特色,搭建了一套社区生活圈公共服务设施评价模型。利用该模型可对各类社区进行综合评分和分级,并根据模型评分结果挖掘公共服务设施未来优化方向。此外,还实现了社区生活圈评分的动态计算与展示,为社区服务设施建设选址、路网建设与公共服务设施建设优先级评定等提供决策支持。既可帮助规划者和决策者快速建立对整个区域生活圈建设现状的量化认知,又可助力公共服务设施的优化配置,为社区生活圈公共服务品质评价与提升探寻全新的思路与方法。     

面向带电作业的手臂末端输出力评估方法

为了解决带电作业时手臂末端输出力的准确控制,提出一种基于表面肌电信号（sEMG信号）和支持向量机回归（SVR）实现对手臂末端施力的评估方法.通过手握机械手臂末端的手柄,做往复推拉运动,记录此时手柄处的力传感器的数据F,同时利用3组肌电信号传感器同步采集手臂的肌电信号.将肌电信号提取特征后,与力F组合成样本集合S,在样本集合中随机抽取50%的样本数据作为训练集,分别训练BP神经网络、GRNN神经网络以及SVR神经网络.最后用训练好的神经网络对整个样本集中的力F进行预测,并用均方根误差和相关系数评估模型的预测效果.结果显示,SVR神经网络的预测效果较好,其均方根误差为3.074 0,相关系数为0.951 7.     

基于深度学习的低剂量CT成像算法研究进展

计算机断层扫描成像(CT)技术具有成像速度快分辨率高的优点,广泛应用于医学临床诊断中.然而,提高剂量辐射会引发人体组织器官受损,降低剂量又会造成成像质量严重下降.为解决上述矛盾,在确保成像质量满足临床诊断需求的条件下,研究如何最大程度地降低X射线辐射对人体造成的伤害,己成为低剂量CT成像技术的研究热点.近年来,在人工智...     

高陡堆积体滑坡半坡桩无效锚固深度分析

半坡桩与普通抗滑桩的受力机制不同,用常规的设计方法半坡桩的锚固深度不足,可能导致治理工程失效。为了分析半坡桩无效锚固深度,在分析高陡堆积体滑坡特点的基础上,根据抗滑桩受力机制重新厘定了半坡桩的概念;以弹性半坡桩为例,用数值分析方法重点研究了弹性半坡桩无效锚固深度与总的锚固深度、滑面倾角及滑坡推力的关系。结果表明,弹性半坡桩的无效锚固深度受总的锚固深度影响较小,当总的锚固深度增加时,无效锚固深度在小范围内波动;弹性半坡桩的无效锚固深度与滑面倾角及滑坡推力呈指数正相关性,随着滑面倾角及滑坡推力的增加,无效锚固深度也在增加。     

雅鲁藏布江缝合带西段错不扎铬铁矿特征及形成环境

雅鲁藏布江蛇绿岩带是国内铬铁矿床出露点最多,且铬铁矿石储量、产量最大的一个蛇绿岩带。根据空间展布规律,该岩带被划分为东段(曲水—墨脱)、中段(昂仁—仁布)和西段(萨嘎至中印边境)3部分。其中,西段自萨嘎以西分为南、北两支亚带。长期以来的研究工作主要集中在东段和中段,西段的研究程度非常薄弱,尤其是北亚带。不同区段研究程度的不平衡十分不利于雅鲁藏布江蛇绿岩带内铬铁矿找矿工作的开展。错不扎蛇绿岩体位于雅鲁藏布江缝合带西段的北亚带,呈北西-南东向带状产出,主要由方辉橄榄岩组成,并普遍发育基性岩脉。野外地质调查在该蛇绿岩体中发现了多个铬铁矿化点,矿化体呈透镜状产于方辉橄榄岩中,出露地表的长度为0.5～1m,厚为0.2～0.5 m,矿石均为致密块状。电子探针分析结果表明,错不扎铬铁矿属于高铬型铬铁矿,铬尖晶石的Cr#[=100×Cr/(Cr+Al)]为75～78,Mg#[=100×Mg/(Mg+Fe2+)]为66～69。计算结果表明,母岩浆的FeO/MgO比值为0.51～0.65,Al2O3和Ti O2含量分别为11.27%～12.1%和0.19%～0.4%,与玻安质岩浆的化学成分相当。然而,针状单斜辉石出溶体的发现指示错不扎铬铁矿可能还经历了一个深部作用过程。     

西藏雅鲁藏布江缝合带中段仁布豆荚状铬铁矿成因及构造意义

藏南雅鲁藏布江缝合带为目前国内铬铁矿储量最大的缝合带.本文报道了缝合带中段仁布蛇绿岩的豆荚状铬铁矿床,围绕矿床特征开展成因探讨,对缝合带的形成演化和成矿作用提供新制约.仁布蛇绿岩呈近东西走向带状产出,主要由近30个大小不等的地幔橄榄岩体组成.地幔橄榄岩体主要为经历不同程度蛇纹石化的方辉橄榄岩和少量纯橄岩.在纯橄岩和方辉...     

山西湿地资源及可持续利用研究

山西湿地主要地各河流流域、湖泊和水库及周围地区,主要由河口（内陆）湿地、充湿地１湖泊湿地、水库湿地和沼泽及草甸湿地等组成总面积经久２１４６ｋｍ＾２。山西湿地有着丰富的自然资源,包括：（１）生物资源有植物１２０９种,其中野大豆为国家３级保护植物;资源植物７类,其中饲草植物蕴藏量最大;植被资源有７０个群系,以 一植物群落占绝对优势;动物４５５种,其中国家１．２缘保护动物１７种,鱼类资源７０种。（２）土