吴玉其（副教授）

»姓名：吴玉其

»系属：地质系

»学位：博士

»职称：副教授

»专业：地质工程/地质学

»导师类别：硕士生导师  

»电子邮箱：wuyuqi@upc.edu.cn

»通讯地址：青岛市黄岛区长江西路66号

◎研究方向

1. 非常规-深层油气地质学，油气田开发地质学，油藏描述

2. 数字岩心分析，成岩作用，水岩相互作用，数字岩石物理

3. 人工智能，地学大数据，智能成储，储层智能建模

◎教育经历

2012. 09-2016. 07，长安大学，资源勘查工程（卓越工程师），学士

2016. 09-2021. 06，中国石油大学（华东），地质资源与地质工程，博士

2018. 11-2020. 05，University of Wyoming，石油工程，联合培养

◎工作经历

2021. 10-2024. 04，中国石油大学（华东），博士后、讲师

2024. 01-至今，   中国石油大学（华东），副教授

◎学术兼职

1. SCI期刊Computers & Geosciences编委、Lithosphere副主编

2. Petroleum Science、Advances in Geo-Energy Research、International Journal of Coal Science & Technology、吉林大学学报（地球科学版）、煤炭科学技术、Rock Mechanics Bulletin、Subsurface Exploration and Exploitation等期刊青年编委

3. EAGE、InterPore协会会员及年会分会场主席

◎主讲课程

◎指导研究生及博士后

热烈欢迎资源勘查工程、地质学、勘查技术与工程、石油工程、计算机、物理、数学、力学等相关专业的同学报考研究生，帮助每位学生找到适合的科研方向，提供优质科研项目和顶级科研平台，助力每位学生成长成才！

◎承担项目

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、校企合作项目10余项。

1.国家自然科学基金青年科学基金，基于多组分数字岩心的纹层组合样式对页岩岩石物理性质控制作用研究，2023-2025

2.山东省级人才工程项目，纹层状页岩数字岩心及岩石物理性质，2025-2027

3.国家科技重大专项任务，基于智能岩心的储层物性和电性评价，2025-2030

4.全国博士后创新人才支持项目，基于热模拟实验的深层页岩三维数字岩心动态建模及物性响应特征研究，2021-2023

5.山东省自然科学基金青年项目，富有机质泥页岩生烃过程中三维数字岩心动态建模及物性响应研究，2023-2025

6.校企合作项目，中海石油(中国)东海西湖石油天然气作业公司，特低渗储层渗流特征的多尺度岩石物理分析与产能评价，2025-2026

8.校企合作项目，中国石油集团科学技术研究院有限公司，基于数字岩心数值模拟方法的长石溶孔含气特征研究，2024-2024

9.校企合作项目，中国石油天然气股份有限公司勘探开发研究院，全直径CT及微纳米CT扫描，2025-2025

10.校企合作项目，中石化石油物探技术研究院有限公司，基于数字岩心的纹层状页岩岩石物理响应机理研究，2025-2026

11. 国家自然科学基金面上项目，湖相富有机质泥页岩中文石的成因机制及其环境意义，2024-2027

12. 校企合作项目，渤海典型变质岩潜山油藏不同尺度裂缝精细刻画及表征研究，2023-2025

13. 校企合作项目，陆相页岩孔隙润湿性定量表征及其对油水赋存的影响研究，2022-2023

14. 国家科技重大专项，低渗-致密油藏描述新方法与开发模式，2017-2020

15. 国家科技重大专项，储层构型表征及剩余油分布规律研究，2016-2018

◎获奖情况

1. Marine and Petroleum Geology期刊2021年度最佳论文奖

2. 山东省优秀博士学位论文

3. 康菲石油中国“未来之路”能源创新研究项目亚军

4. 博士研究生国家奖学金

◎荣誉称号

1. 全国博士后创新人才支持计划

2. 山东省级人才工程入选者

3. 孙越崎优秀学生奖

4. 李四光优秀学生奖提名奖（博士）

5 山东省高等学校优秀学生

6. 山东省优秀毕业生

7. 中国石油大学（华东）第十五届研究生学术十杰

8. 中国石油大学（华东）十大学生标兵

◎著作

1.《Digital Rock Modeling: A Review》Wiley Publisher. 

◎论文

部分代表性论文如下，详见学术主页https://www.researchgate.net/profile/Yuqi-Wu-4 

1. Wu Y, Yang J, Liu K*, et al. Effects of lamina on petrophysical properties and brittleness of shales: Insight from lamina-scale experiment and fracture propagation simulations [J]. Petroleum Science, 2026, 23 (4): 1728-1753.

2. Talha M, Wu Y*, Wang J*, et al. Pore-scale simulation of CO₂-induced rock dissolution: Considering the effects of reaction rate [J]. Fuel, 2027, 427 (1): 140024.

3. Li G, Lin C*, Wu Y*, et al. Machine learning applications in tight porous media: Challenges, advances, and future directions [J]. Earth-Science Reviews, 2025, 271, 105306.

4. Wu Y, Tahmasebi P, Liu K, et al. Modeling the physical properties of gas hydrate‐bearing sediments: Considering the effects of occurrence patterns [J]. Energy, 2023, 278: 127674.

5. Wu Y, Tahmasebi P, Yu H, et al. Pore-scale 3D dynamic modeling and characterization of shale samples: Considering the effects of thermal maturation [J]. Journal of Geophysical Research: Solid Earth, 2020, 125(1): e2019JB018309.

6. Wu Y, Tahmasebi P, Lin C, et al. Effects of micropores on geometric, topological and transport properties of pore systems for low-permeability porous media [J]. Journal of Hydrology, 2019, 575: 327-342.

7. Wu Y, Tahmasebi P, Lin C, et al. A comprehensive study on geometric, topological and fractal characterizations of pore systems in low-permeability reservoirs based on SEM, MICP, NMR, and X-ray CT experiments [J]. Marine and Petroleum Geology, 2019, 103: 12-28.

8. Wu Y, Tahmasebi P, Liu K, et al. Two-phase flow in heterogeneous porous media: A multiscale digital model approach [J]. International Journal of Heat and Mass Transfer, 2022, 194: 123080.

9. Wu Y, Tahmasebi P, Lin C, et al. Multiscale modeling of shale samples based on low- and high-resolution images [J]. Marine and Petroleum Geology, 2019, 109: 9-21.

10. Wu Y, Lin C, Yan W, et al. Pore-scale simulations of electrical and elastic properties of shale samples based on multicomponent and multiscale digital rocks [J]. Marine and Petroleum Geology, 2020, 117: 104369.

11. Wu Y, Tahmasebi P, Lin C, et al. A comprehensive investigation of the effects of organic-matter pores on shale properties: A multicomponent and multiscale modeling [J]. Journal of Natural Gas Science and Engineering, 2020, 81: 103425.

12. Wu Y, Tahmasebi P, Lin C, et al. Using digital rock physics to investigate the impacts of diagenesis events and pathways on rock properties [J]. Journal of Petroleum Science and Engineering, 2022, 208: 108025.

13. Wu Y, Tahmasebi P, Lin C, et al. Quantitative characterization of non-wetting phase in water-wet porous media based on multiphase flow experiment and numerical simulation[J]. Journal of Petroleum Science and Engineering, 2020, 188: 106914.

◎学术交流

1. 基于多矿物数字岩心的成岩作用模拟及应用[C], 第八届全国沉积学大会. 2025年. 北京, 中国.

2. Effects of lamina combination on physical properties of shale samples based on 3D multimineral digital rocks [C], 17th Annual InterPore Meeting. 2025. New Mexico, USA and Online.

3. Simulation of Feldspar Dissolution in Sedimentary Rocks: Integrating Digital Core and Chemical Reaction Kinetics [C], 17th Annual InterPore Meeting. 2025. New Mexico, USA and Online.

4. 基于目标的沉积成岩作用模拟及三维成岩演化模型构建 [C], 第十七届全国古地理学及沉积学会议. 2023年. 青岛, 中国.

5. Deep Learning for Accurate Prediction of Physical Properties of Heterogeneous Digital Rocks [C], 2023 84th EAGE Annual Conference & Exhibition, 2023. Vienna, Austria.

6. Pore-scale characterization and modeling of heterogeneous shale samples based on deep learning [C], 15th Annual InterPore Meeting. 2023. Edinburgh, United Kingdom and Online.

7. Application of digital rock physics to the analysis of the effects of diagenesis on petrophysical properties. [C], 2022 AAPG International Conference and Exhibition, 2022. Cartagena, Colombia and Online.

8. Modeling and characterization of multimineral and multiscale digital rocks of shale samples [C], 2022 AAPG International Conference and Exhibition, 2022. Cartagena, Colombia and Online.

9. Gas flow simulation in multiscale and multimineral digital rocks of shale samples [C], 14th Annual InterPore Meeting, 2022. 2022. Abu Dhabi, United Arab Emirates and Online.

10. Digital rock techniques to study physical properties of hydrate‐bearing sediments: Considering hydrate distribution patterns[C], 14th Annual InterPore Meeting. 2022. Abu Dhabi, United Arab Emirates and Online.

11. Digital rock techniques to investigate impact factors of elastic and electrical properties. [C], First International Meeting for Applied Geoscience & Energy. Society of Exploration Geophysicists, 2021, Denver, USA and Online.

12. Pore-scale investigation of effects of organic-matter pores on shale properties based on multicomponent and multiscale digital rocks [C], 12th Annual InterPore Meeting. 2020. Online.

13. Reconstruction of 3D pore space using multiple-point statistics based on a 2D training image [C], AAPG Annual Convention &Exhibition 2018, 2018. Salt Lake City, USA.

◎专利

1.多尺度数字岩心建模方法、系统、存储介质及应用，ZL 2023 1 0279387.8

2. 一种泥页岩岩心归位方法，ZL 2024 1 1793184.1

3. 一种非均质页岩代表性体积单元的确定方法及相关装置，ZL 2024 1 1001067.7

4. 纳米精度毫米尺度数字岩心重构方法、装置、设备及介质，ZL202610242964.X

5. 一种三维多矿物数字岩心建模方法，ZL202610143044.2