"蒙脱石-伊利石"转化过程中矿物的固体酸性和微结构变化及其对催化生烃的影响与机理研究

项目名称： "蒙脱石-伊利石"转化过程中矿物的固体酸性和微结构变化及其对催化生烃的影响与机理研究

项目编号： No.41272059

项目类型： 面上项目

立项/批准年度： 2013

项目学科： 天文学、地球科学

项目作者： 袁鹏

作者单位： 中国科学院广州地球化学研究所

项目金额： 84万元

中文摘要： "粘土矿物对生烃的作用"是油气成因理论中待解的重要科学问题。粘土矿物催化生烃的微观界面作用机制至今不明，是阻碍该问题获得解决的瓶颈。为此，本项目从固体酸性和微结构这两个影响粘土矿物催化生烃的关键矿物学因素入手，以油气形成过程中最典型的"蒙脱石-伊利石"相变之端元和过渡（混层）粘土矿物为研究对象，探索其固体酸性（酸位类型、浓度及强度）和微结构（微形貌、层间微结构和孔结构）在相转化中的变化和机理；并选用合适的模型有机质模拟生烃母质，制备粘土矿物-有机质层外/层间复合物。在此基础上，构建粘土矿物催化有机质的高温高压界面反应体系，以粘土矿物-有机质复合物为反应物，开展生烃实验（含生烃动力学）研究。根据对反应产物的综合分析，及其与粘土矿物性质、结构的对比分析，揭示"蒙脱石-伊利石"转化中固体酸性和微结构变化对有机质特征基团催化分解的影响和机理，为探明粘土矿物催化生烃的微观机制提供理论和实验依据。

中文关键词： 蒙脱石；伊利石；催化生烃；固体酸性；微结构

英文摘要： The role of clay minerals for hydrocarbon generation is a critical problem, yet to be adequately resolved, in the formation theory of oil and gas. So far, the micro-mechanisms of the hydrocarbon generation based on the catalytic reaction on clay mineral still remain unclear, resulting in a bottleneck for the figuring out of the problem. The present proposal starts with the two key mineralogical factors influencing on the hydrocarbon generation, the solid acidity and microstructure of clay minerals, and orient toward the end-member and intermediate minerals of the montmorillonite - illite transformation which is the most characteristic in the hydrocarbon generation. The planning work includes the investigation on the changes of the solid acidity (the types, concentration and strength of the solid acid sites) and microstructure (micro-morphology, interlayer microstructure and porosity) during the mineral phase-transformation and some key medium conditions, and the preparation of the hybrid of clay mineral and some organocompounds, which are selected as the model organics for the simulation of the hydrocarbon-sourced organics. The organocompounds will be located both inside and outside the interlayer region of clay minerals for comparison purpose. The resulting hybrid materials will be used as the starting reactant

英文关键词： montmorillonite；illite；hydrocarbon-generation by catalysis；solid acidity；microstructure