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作品数:4 被引量:60H指数:3
相关作者:杨家喜刘良王超陈丹玲杨文强更多>>
相关机构:西北大学长安大学中国地质大学更多>>
发文基金:国家自然科学基金国家重点基础研究发展计划更多>>
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超高压岩石中矿物显微出溶结构研究进展、面临问题与挑战被引量:15
2009年
造山带岩石中一些矿物显微出溶结构的深入研究,不仅成为识别其赋存岩石是否经历超高压变质的标志之一,而且在了解超高压岩石俯冲深度及其动力学演化过程等研究方面发挥着重要作用.然而,如何区分认定某些矿物的显微结构是"出溶结构"还是"非出溶结构",并准确解析这些显微结构的地质内涵是目前超高压研究亟待解决的科学难题之一.从矿物出溶作用的基本概念出发,依据前人关于超高压与超深地幔岩石中一些矿物出溶结构的研究成果,本文强调应从出溶矿物精细的几何学特征以及出溶前后矿物之间化学成分是否一致两个方面的研究,综合分析判别一些矿物的显微结构是"出溶结构"还是"非出溶结构";进一步强调提出解析矿物出溶结构能否作为超高压变质的标志及其指示的温压环境等地质内涵的关键,是要加强对出溶母体矿物在高温高压条件下的晶体化学行为及其分解与变化规律的全面深入的了解;同时提出:把高温高压实验与天然岩石样品中的显微结构观察以及多种矿物微区分析测试手段有机结合,深入开展对造山带岩石中发现的各种矿物的显微出溶结构的研究,不仅对深化超高压变质作用以及大陆深俯冲研究提供重要信息和关键性的约束条件,而且有望对陆壳深俯冲以及引发的壳幔交换作用等固体地球科学重要问题提供新认识.
刘良杨家喜章军锋陈丹玲王超杨文强
关键词:超高压变质作用出溶结构高温高压实验
超硅石榴石的偶合类质同象置换及辉石、金红石、磷灰石和石英的出溶被引量:3
2003年
超高压条件下辉石溶入石榴石使石榴石出现Si~Ⅵ+M~Ⅵ=Al~Ⅵ+Al~Ⅵ和Si~Ⅵ+Na~Ⅷ=Al~Ⅵ+M~Ⅷ偶合置换而形成超硅石榴石,其程度随压力增高而增强.超硅石榴石以及在减压过程中石榴石出溶辉石、金红石、磷灰石和石英的现象已在天然岩石中发现,在幔源岩石以及与板块深俯冲有关的超高压变质作用研究方面具有重要的意义.Ti通过对Si的置换、P通过P~Ⅳ+Na~Ⅷ=Si~Ⅳ+Ca~Ⅷ偶合置换、K通过Si~Ⅵ+K~Ⅷ=Al~Ⅵ+M~Ⅷ偶合置换、水通过[(OH)_4]^(4-)=[SiO_4]^(4-)置换即[4H]^(4+)=Si^(4+)置换进入石榴石晶格.单斜辉石中的Eskola辉石组分M_(0.5)AlSi_2O_6可能与一般辉石组分M_2Si_2O_6在超高压条件下一道进入石榴石,将在石榴石中出现出Si~Ⅵ+0.5□~Ⅷ=Al~Ⅵ+0.5M~Ⅷ偶合置换.这种偶合置换的存在是导致金红石、磷灰石和石英在石榴石中出溶的关键.根据这一新的偶合置换,本文给出了两个新的分解反应,作为这些矿物在石榴石中出溶的理论模型.实际的出溶可以是多个分解反应的联合.
杨家喜刘良
关键词:辉石金红石磷灰石石英
Ultrahigh pressure (>7 GPa) gneissic K-feldspar (-bearing) garnet clinopyroxenite in the Altyn Tagh, NW China: Evi- dence from clinopyroxene exsolution in garnet被引量:38
2005年
The exsolution of clinopyroxene and rutile in coarse-grain garnet is found in the gneissic K-feldspar(-bearing) garnet clinopyroxenite from Yinggelisayi in the Altyn Tagh, NW China. The maximum content of the exsolved clinopyroxene in the garnet is up to >5% by volume. The reconstructed precursor garnet (Grt1) before exsolution has a maximum Si content of 3.061 per formula uint, being of supersilicic or majoritic garnet. The peak-stage metamorphic pressure of >7 GPa is estimated using the geobarometer for volume percentage of exsolved pyroxene in garnet and the Si-(Al+Cr) geobarometer for majoritic garnet, and the temperature of about 1000℃ using the ternary alkali-feldspar geothermometer and the experimental data of ilmen- ite-magnetite solid solution. The protoliths of the rocks are intra-plate basic and intermediate ig- neous rocks, of which the geochemical features indicate that they are probably the products of the evolution of basic magma deriving from the continental lithosphere mantle. The rocks are in outcrops associated with ultrahigh pressure garnet-bearing lherzolite and ultrahigh pressure garnet granitoid gneiss. All of these data suggest that the ultrahigh pressure metamorphic rocks in the Altyn Tagh are the products of deep-subduction of the continental crust, and such deep- subduction probably reaches to >200 km in depth. This may provide new evidence for further discussion of the dynamic mechanism of the formation and evolvement of the Altyn Tagh and the other collision orogenic belts in western China.
LIU Liang1,3, CHEN Danling1, ZHANG Anda1, SUN Yong1, WANG Yan1, YANG Jiaxi1,2 & LUO Jinhai1 1. Key Laboratory of Continental Dynamics of the Ministry of Education of China, Northwest University, Xi’an 710069, China
关键词:K-FELDSPARGARNETCLINOPYROXENEEXSOLUTIONGARNET
Exsolution microstructures in ultrahigh-pressure rocks:Progress, controversies and challenges被引量:10
2009年
Exsolution microstructures in minerals of rocks from orogenic belts played an important role in recognition of ultrahigh-pressure (UHP) metamorphism in their host rocks by defining the subduction depth and improving our understanding of the dynamics during the subduction and exhumation of UHP rocks. However, it is a challenging scientific topic to distinguish the 'exsolution microstructures' from the 'non-exsolution microstructures' and decipher their geological implications. This paper describes the subtle differences between the 'exsolution microstructures' and the 'non-exsolution microstructures' and summarizes the progress in studies of exolution microstructures from UHP rocks and mantle rocks of ultra-deep origin. We emphasize distinguishing the 'exsolution microstructures' from the 'non-exsolution microstructures' based on their geometric topotaxy and chemistry. In order to decipher correctly the exsolution microstructures, it is crucial to understand the changes of chemistry and habits of host minerals with pressure and temperature. Therefore, it is important to combine observations of exsolution microstructure in natural rocks with experimental results at high pressure and temperature and results of micro-scale analyses. Such studies will improve our understanding of the UHP metamorphism and cast new lights on solid geoscience issues such as deep subduction of continental crusts and crust-mantle interactions.
LIU LiangYANG JiaXiZHANG JunFengCHEN DanLingWANG ChaoYANG WenQiang
关键词:超高压岩石超高压变质岩石超高压变质作用壳幔相互作用科学主题
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