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姓名: |
远光辉 |
系属: |
地质系 |
学位: |
博士 |
职称: |
教授 |
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专业: |
油气储层地质学 |
导师类别: |
博导 |
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电子邮箱: |
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联系电话: |
通讯地址: |
青岛市黄岛区长江西路66号工科楼C座 |
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个人概况 远光辉,光华学者 特聘教授,博士生导师,国家优青基金获得者、山东省"泰山学者"青年专家。长期从事油气储层地质学、沉积盆地地质流体-岩石相互作用及其资源环境效应研究,发表SCI和EI论文50篇,其中第一/通讯作者在Nature Communications、ESR、GCA、AAPG Bulletin、中国科学-地球科学等期刊发表SCI/EI收录论文20篇,授权发明专利6项,获山东省科技进步一等奖和中国石油与化学工业联合会科技进步一等奖各1项。担任期刊《AAPG Bulletin》和《Marine and Petroleum Geology》副编辑,担任《石油勘探与开发》和《Petroleum Research》编委。 深层油气富集机理与分布规律 2011/09-2015/06,中国石油大学(华东),地质学,博士 2013/09-2014/09,Durham University,联合培养 2009/09-2011/07,中国石油大学(华东),地质学,硕士 2005/09-2009/07,中国石油大学(华东),资源勘查工程,学士 2015.07-2015.11 中国石油大学(华东),博士后 2018.01-2019.12 中国石油大学(华东),副教授 2021.01-今 中国石油大学(华东),教授 《AAPG Bulletin》和《Marine and Petroleum Geology》Associate Editor 《石油勘探与开发》和《Petroleum Research》编委 本科生课程:《地质学基础》、《海底矿产资源》、《专业外语》 研究生课程:《Diagenesis and Reservoir Evaluation》 指导博士生4人,硕士研究生10人,协助指导博士和硕士研究生10人。 主持和参与国家自然科学基金、国家科技重大专项、省部级项目、校企合作课题10余项。 [1] 国家自然科学基金基础科学中心项目A类(42488101),圈层相互作用与陆相油气,2024.01-2029.12,在研,骨干成员 [2] 国家自然科学基金优秀青年基金项目(42222208),含油气盆地地质流体-岩石相互作用,2023.01-2025.12,在研,主持 [3] 国家自然科学基金(面上项目41872140):碎屑岩储层中长石溶蚀动力学及定量预测研究,2019.01-2022.12,结题,主持. [4] 国家自然科学基金(青年项目41602138):富长石砂岩油气藏中长石成岩演化及其与烃类裂解的相关性研究,2017.01-2019.12,结题,主持. [5] 国家自然科学基金(中-英合作交流项目41911530189):富长石砂岩储层中的水-岩作用及其碳封存意义,2019.04-2021.03,结题,主持. [6] 崂山实验室,崂山实验室"十四五"重大项目子课题,2021QNLM020001-2-3,南海深层储层成岩作用与发育机理,2021-11 至 2024-12,120万元,在研,主持 [7] 山东省人民政府,山东省泰山学者青年专家 项目,No.tsqn201909061,深层地质流体-岩石相互作用机理,2020-01 至 2024-12,50万元,在研,主持 [8] 中海油深圳分公司,惠州-陆丰地区古近系碎屑岩储层成岩演化特征及物性响应研究,CCL2021SZPS0101,126.8万,结题,主持 2019年 山东省科技进步一等奖,5/12 2018年 中国石油和化学工业联合会科技进步一等奖,4/15 2016年 山东省优秀博士学位论文,1/1 2015年 AAPG Grants-In Aid,1/1 国家自然科学基金优青基金获得者(2022) 山东省 泰山学者青年专家,2020 青岛市西海岸新区第四批领军人才,2021 中国石油大学(华东)青春建功新时代先进个人,2019 [1]远光辉、操应长、王艳忠.《碎屑岩油气储藏中长石和碳酸盐矿物溶蚀机理及其物性响应》,石油工业出版社,北京,2016. [2]Jon Gluyas,Guanghui Yuan. [1] Guanghui Yuan,Jin Zihao,Cao Yingchang,Hans-Martin Schulz,Jon Gluyas,Keyu Liu,He Xingliang,Wang Yanzhong. Microdroplets initiate organic-inorganic interactions and mass transfer in thermal hydrous geosystems,Nature Communications,2024,15: 4960 [2]Yuan Guanghui,Wu Shuqi,Cao Yingchang,Jin Zihao,Liu Keyu,Wang Yanzhong. Mixing processes and patterns of fluids in alkane-CO2-water systems under high temperature and high pressure-Microscopic visual physical thermal simulations and molecular dynamics simulations,Science China. Earth Sciences,2023,66(7): 1622-1646 [3]Guang-Hui Yuan,Zi-Hao Jin,Ying-Chang Cao,Ke-Yu Liu,Jon Gluyas,Yan-Zhong Wang,Ke-Lai Xi. Evolution of nC16H34-water–mineral systems in thermal capsules and geological implications for deeply-buried hydrocarbon reservoirs,Geosciences Frontiers,2022,13(2):101322. [4]Cao Yingchang,Yuan Guanghui,Wang Yanzhong,et al. Successive formation of secondary pores via feldspar dissolution in deeply buried feldspar-rich clastic reservoirs in typical petroliferous basins and its petroleum geological significance,2022,65:1673-1703. [5]Zihao Jin,Guanghui Yuan,Yingchang Cao,Keyu Liu,Yanzhong Wang,Jianye Sun,Xiluo Hao,Ling Zhou,Yihan Wei,Shuqi Wu. Interactions between hydrocarbon-bearing fluids and calcite in fused silica capillary capsules and geological implications for deeply-buried hydrocarbon reservoirs,SCIENCE CHINA Earth Sciences,2022,65(2): 299-316. [6] Guanghui Yuan,Yingchang Cao,et al.Genetic mechanisms of Permian Upper Shihezi sandstone reservoirs with multi-stage subsidence and uplift in the Huanghua Depression,Bohai Bay Basin,East China. Marine and Petroleum Geology,2021,124:1-25. [7] Guanghui Yuan,Yingchang Cao,et al. Coupled mineral alteration and oil degradation in thermal oil-water-feldspar systems and implications for organic-inorganic interactions in hydrocarbon reservoirs. Geochimica Et Cosmochimica Acta,2019,248:61-87. [8] Guanghui Yuan,Yingchang Cao,et al. A review of feldspar alteration and its geological significance in sedimentary basins: from shallow aquifers to deep hydrocarbon reservoirs. Earth-Science Reviews,2019,191:114-140. [9] Guanghui Yuan,Yingchang Cao,Jon Gluyas,et al. Reactive transport modeling of coupled feldspar dissolution and secondary mineral precipitation and its implication for diagenetic interaction in sandstones. Geochimica Et Cosmochimica Acta,2017,207: 232-255. [10] Guanghui Yuan,YingchangCao,Jon Gluyas,et al. Feldspar dissolution,authigenic clays and quartz cements in open and closed sandstone geochemical systems during diagenesis. AAPG Bulletin,2015,99(11)2121-2154. [11]Guanghui Yuan,Yingchang Cao,Longwei Qiu,et al. Genetic Mechanism of High quality reservoirs in permian tight fan delta conglomerates at the northwestern margin of the Junggar Basin,Northwestern China. AAPG Bulletin,2017,101(12)1995-2019. [12] Guanghui Yuan,Yingchang Cao,Jon Gluyas,et al. Petrography,fluid inclusion,isotope and trace element constraints on the origin of quartz cementation and feldspar dissolution and the associated fluid evolution in arkosic sandstones. AAPG Bulletin,2018,102,5:761-792. [13] Guanghui Yuan,Yingchang Cao,Zhenzhen Jia,Jon Gluyas,et al. Selective dissolution of feldspars in the presence of carbonates: The way to generate secondary pores in buried sandstones by organic CO2.Marineand Petroleum Geology,2015,60:105-119. [14] Guanghui Yuan,Jon Gluyas,Yingchang Cao,et al. Diagenesis and reservoir quality evolution of the Eocene sandstones in the northern Dongying Sag,Bohai Bay Basin,East China. Marine & Petroleum Geology,2015,62:77-89. [14] Guanghui Yuan,Yingchang Cao,Yongchao Zhang,et al. Diagenesis and reservoir quality of sandstones with ancient "deep" incursion of meteoric freshwater——An example in the Nanpu Sag,Bohai Bay Basin,East China. Marine & Petroleum Geology,2017,82:444-464. [16] Cao Yingchang,Yuan Guanghui,et al. Characteristics and origin of abnormally high porosity zones in buried Paleogene clastic reservoirs in the Shengtuo area,Dongying Sag,East China. Petroleum Science,2014,11:346-362. [17] 操应长,远光辉,等.含油气盆地深层—超深层碎屑岩油气勘探现状与优质储层成因研究进展. 石油学报,2022,43(1):112-140. [18] 远光辉,操应长,葸克来,等.东营凹陷北带古近系碎屑岩储层长石溶蚀作用及其物性响应.石油学报,2013,34(5):853-866. [19] 远光辉,操应长,贾珍臻,等.含油气盆地中深层碎屑岩储层异常高孔带研究进展[J].天然气地球科学,2015,26(1):28-42. [20] 远光辉,操应长,杨田,等.论碎屑岩储层成岩过程中有机酸的溶蚀增孔能力[J].地学前缘,2013,20(5):207-219. [21] 操应长,远光辉,等.东营凹陷北带古近系中深层异常高孔带类型及特征.石油学报,2013,34(4):684-691. [22] 操应长,远光辉,等.准噶尔盆地北三台地区清水河组低渗透储层成因机制.石油学报,2012,33(5):758-771 [1] 远光辉.一种厘定砂岩储层中古成岩流体来源的方法,2019.1.29,中国,ZL2016 10985115.X [2] 远光辉;操应长;王孝明;邱隆伟;王越磊.储层假缝识别和物性校正方法,2018.4.13,中国,ZL201510970047.5 [3] 远光辉,操应长,等. 储层中深部异常高孔隙带类型划分及定量厘定方法,2020.12.18,中国,ZL201510970050.7 [4] 远光辉,操应长,等. 一种岩-水-烃模拟实验方法,2021.08.31,中国,ZL201910080767.2 [5] 远光辉,靳子濠,操应长,等. 一种"烃-水-岩"相互作用的热模拟综合实验方法,2022-2-15,中国,ZL201910535089.4 [6] 远光辉; 靳子濠; 操应长; 刘可禹. 一种基于同位素示踪的"烃-水-岩"相互作用热模拟实验方法,2023-06-13,中国,ZL202210448976.X |
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