In-situ observation for formation and dissociation of carbon dioxide hydrate in porous media by magnetic resonance imaging 被引量：5

In-situ observation for formation and dissociation of carbon dioxide hydrate in porous media by magnetic resonance imaging

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摘要 The study of formation and dissociation of CO 2 hydrate in porous media was characterized by magnetic resonance imaging (MRI) system in in situ conditions. This work simulated porous media by using glass beads of uniform size. The growth and dissociation habit of CO2 hydrate was observed under different temperature and pressure conditions. The induction time and the hydrate saturation during the growth and dissociation process in different sizes of porous media were obtained by using the MRI signal intensity. The results indicate that hydrate growth rate and the induction time are affected by the size of porous media, pressure, and degree of supercooling. There are three hydrate growth stages, i.e., initial growth stage, rapid growth stage and steady stage. In this study,the CO2 hydrate forms preferentially at the surface of vessel and then gradually grows inward. The hydrate tends to cement the glass beads together and occupies the pore gradually. As the hydrate decomposes gradually, the dissociation rate increases to the maximum and then decreases to zero. The study of formation and dissociation of CO2 hydrate in porous media was characterized by magnetic resonance imaging （MRI） system in in situ conditions. This work simulated porous media by using glass beads of uniform size. The growth and dissociation habit of CO2 hydrate was observed under different temperature and pressure conditions. The induction time and the hydrate saturation during the growth and dissociation process in different sizes of porous media were obtained by using the MRI signal intensity. The results indicate that hydrate growth rate and the induction time are affected by the size of porous media, pressure, and degree of supercooling. There are three hydrate growth stages, i.e., initial growth stage, rapid growth stage and steady stage. In this study, the CO2 hydrate forms preferentially at the surface of vessel and then gradually grows inward. The hydrate tends to cement the glass beads together and occupies the pore gradually. As the hydrate decomposes gradually, the dissociation rate increases to the maximum and then decreases to zero.

作者 CHENG ChuanXiao ZHAO JiaFei SONG YongChen ZHU ZiHao LIU WeiGuo ZHANG Yi YANG MingJun YU XiChong

机构地区 Key Laboratory of Ocean Energy Utilization and Energy Conservation of Ministry of Education CNOOC Research Center

出处《Science China Earth Sciences》 SCIE EI CAS 2013年第4期611-617,共7页 中国科学（地球科学英文版）

基金 supported by the State Key Development Program for Basic Research of China (Grant No. 2009CB219507) National Natural Science Foundation of China (Grant Nos. 51006017 & 50736001) National Science and Technology Major Project (Grant No. 2011ZX05026-004)

关键词 magnetic resonance imaging carbon dioxide hydrate porous media SATURATION induction time growth and dissocia- tion rate 多孔介质磁共振成像水合物二氧化碳和分解原位观察生长过程压力条件

分类号 P744.4 [天文地球—海洋科学]

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