◎学习与工作经历
2024.02-至今:成都理工大学能源学院(页岩气现代产业学院),副研究员,博导
2022.03-2024.01:成都理工大学地质灾害防治与地质环境保护国家重点实验室,副研究员,硕导
2016.07-2022.02:四川大学建筑与环境学院,助理研究员
2013.09-2016.06:四川大学,岩土工程,博士学位
2010.09-2013.06:四川大学,岩土工程,硕士学位
2006.09-2010.06:四川大学,岩土工程,学士学位
◎研究方向
从事深部岩石力学、深部能源开采方面的研究。
◎主讲课程
(1)石油工程岩石力学
(2)钻完井工程
(3)干热岩压裂技术
(4)地下储气库技术
◎主持或参与科研课题
从事科研项目共20余项,部分如下:
(1)干热岩注采-关井循环过程缝网动态演化机理与取热优化调控研究,国家自然科学基金面上项目(52574031),2026-2029,负责人
(2)深层页岩储层压裂四维地应力预测技术完善与验证,国家科技重大专项 (2025ZD1405304),2025-2030,专题负责人
(3)增强型热储循环注采缝网动态演化与取热智能调控,四川省自然科学基金面上项目(2025ZNSFSC0371),2025-2026,负责人
(4)页岩基质损伤渗透-裂缝内多相流耦合裂缝扩展研究,地质灾害防治与地质环境保护国家重点实验室自主课题(SKLGP2022Z018),2023-2024,负责人
(5)页岩气压裂缝网实时模拟技术研究,中石化涪陵页岩气勘探开发有限公司(31401225-23-FW0499-0066),2023-2024,负责人
(6)水力压裂诱发断层滑移实验研究,中国石油西南油气田分公司(AH2023-0373*2),2023-2024,负责人
(7)冀东油田天然气驱注采井套损机理及防治研究,中国石油天然气股份有限公司冀东油田分公司(80303-AH20230445-03),2023-2024,负责人
(8)低温冲击深层页岩温度裂缝竞争扩展行为研究,自然资源部页岩气资源勘查重点实验室(KLSGE-202103),2022,负责人
(9)酸化压裂液作用下含油页岩裂缝长期导流能力行为研究,四川省科技厅国际科技创新合作项目(2021YFH0118),2021-2023,负责人
(10)页岩裂隙内多相流耦合行为及数值研究,深地科学与工程教育部重点实验室(DUSE201804),2018-2020,负责人
(11)济阳坳陷纹层状页岩油压裂三维裂缝穿层模拟与均衡改造优化研究,中国石油化工股份有限公司胜利油田分公司油气勘探管理中心(30200027-23-ZC0613-0012),2023-2024,技术负责人
(12)超深层压裂裂缝起裂扩展研究,中石化新疆新春石油开发有限责任公司(30203569-23-ZC0613-0012),2023-2024,技术负责人
◎获奖情况
(1)页岩油气藏高导流缝网压裂理论与新技术及规模应用,教育部科学研究优秀成果奖工程技术奖二等奖,2025
(2)Investigating fracture initiation and propagation in deep buried shale due to thermal shock: a numerical approach,重庆市地质学会2024年度优秀科技论文等级评定三等奖,2024
(3)强震区高位落石作用下棚洞立体防护关键技术及工程应用,中国公路学会科学技术一等奖,2024
◎论文
发表SCI论文50余篇,其中一作或通讯作者30余篇:
[1]Zhao Peng, Zhu Haiyan, Zhang Fengshou, Tang Xuanhe, Chen Shijie, Tao Lei, Melennan JohnD. Heat exchange during fluid seepage and heat transfer in EGS heat extraction: Insights from laboratory experiments. Journal of Rock Mechanics and Geotechnical Engineering, 2026.
[2]Xian Hongyu, Zhao Peng*, Zhu Haiyan, Tao Lei, Tang Xuanhe, Lei Ming. Research on hydraulic fracture cross‑layer propagation and bedding plane activation in artificial layered rock fracturing: insight from physical experiments. Rock Mechanics and Rock Engineering, 2025.
[3]Zhao Peng, Zhu Haiyan, Li Gensheng, Chen Zuo, Chen Shijie, Shangguan Shuangtong, Qi Xiaofei. Large-scale physical simulation of injection and production of hot dry rock in Gonghe Basin, Qinghai Province, China. Petroleum Exploration and Development, 2024, 51(3), 741-752.
[4]Liu Jun, Zhao Peng*, Peng Jiao, Xian Hongyu. Insight into the investigation of heat extraction performance affected by natural fractures in enhanced geothermal system (EGS) with THM multiphysical field model. Renewable Energy, 2024, 231, 121031.
[5]Zhao Peng, Liu Jun, Zhang Yu. Experimental and numerical investigations on buffer performance of geofoam subjected by the impact of falling rocks with respect to different shapes. Geotextiles and Geomembranes, 2023, 51(4), 108-124.
[6]Zhao Peng, Liu Jun, Derek Elsworth. Numerical study on a multifracture enhanced geothermal system considering matrix permeability enhancement induced by thermal unloading. Renewable Energy, 2023, 203, 33-44.
[7]Zhao Peng, Yuan Song, Li Liangpu, Ge Qi, Liu Jun, Du Longhuan. Experimental study on the multi-impact resistance of a composite cushion composed of sand and geofoam. Geotextiles and Geomembranes, 2021, 49(1), 45-56.
[8]Zhao Peng, Xie Lingzhi, Fan Zhichao, Deng Lei, Liu Jun. Mutual interference of layer plane and natural fracture in the failure behavior of shale and the mechanism investigation. Petroleum Science, 2021, 18(2), 618-640.
[9]Liu Jun, Xie Lingzhi, He Bo, Zhao Peng*. Performance of free gases during the recovery enhancement of shale gas by CO2 injection: a case study on the depleted Wufeng–Longmaxi shale in northeastern Sichuan Basin, China. Petroleum Science, 2021, 18(2), 530-545.
[10]Chen Shijie, Zhao Peng*, Jiao Zixi, Zhou Jun, Tang Xuanhe. Time-lag characteristics and strength evolution of rock failure under unloading conditions. Physics of Fluids, 2025, 37, 054106
[11]Zhao Peng, He Bo, Zhang Bo, Liu Jun. Porosity of gas shale: Is the NMR-based measurement reliable? Petroleum Science, 2022, 19(2), 509-517.
[12]Zhao Peng, Xie Lingzhi, He Bo, Liu Jun. Anisotropic permeability influencing the performance of free CH4 and free CO2 during the process of CO2 sequestration and enhanced gas recovery (CS-EGR) from shale. ACS Sustainable Chemistry & Engineering, 2021, 9(2), 914-926.
[13]Cheng Lijun, Zhang Ye, Liu Jun, Lu Zhaohui, Zeng Chunlin, ZhaoPeng*. Numerical modeling of the dynamic variation in multiphase CH4 during CO2 enhanced gas recovery from depleted shale reservoirs. Frontiers of Earth Science, 2021, 15(4), 790-802.
[14]He Bo, Liu Jun, Zhao Peng*, Wang Junfeng. PFC2D-based investigation on the mechanical behavior of anisotropic shale under Brazilian splitting containing two parallel cracks. Frontiers of Earth Science, 2021, 15(4), 803-816.
[15]Liu Jun, Xie Lingzhi, He Bo, Gan Quan, Zhao Peng*. Influence of anisotropic and heterogeneous permeability coupled with in-situ stress on CO2 sequestration with simultaneous enhanced gas recovery in shale: Quantitative modeling and case study. International Journal of Greenhouse Gas Control, 2021, 104, 103208.
[16]赵鹏, 朱海燕*, 张丰收. CO2增强页岩气开采及地质埋存的三维数值模拟. 天然气工业, 2024, 44(4), 104-114.
[17]Zhao Peng, Zhu Haiyan. Design and implementation of a virtual experimental teaching system for deep energy exploitation based on digital twin technology. Systems, 2024, 12(10): 386.
[18]Ping Enshun, Zhao Peng*, Zhu Haiyan, Wang Yuzhong, Jiao Zixi, Zhao Qingjie, Feng Gan. Numerical simulation of the simultaneous development of multiple fractures in horizontal wells based on the extended finite element method. Energies, 2024, 17(5), 1057.
[19]Wang Wei, Zhao Peng*, Liao Yisha, Zhang Yuelei, Peng Jiao, Xian Hongyu, Liu Jun. Investigating fracture initiation and propagation in deep buried shale due to thermal shock: a numerical approach. Frontiers in Energy Research, 2023, 11, 1231958.
[20]Yuan Song, Zhao Peng*, Li Liangpu, Wang Xibao, Liu Jun, Zhang Bo. A discrete numerical study of the effect of the thickness and the porosity of the sand cushion on the impact response due to the rockfall. CMES-Computer Modeling in Engineering & Sciences, 2022, 130(3), 1683-1698.
[21]Zhao Peng, Xie Lingzhi, He Bo, Liu Jun. Strategy optimization on industrial CO2 sequestration in the depleted Wufeng-Longmaxi formation shale in the Northeastern Sichuan Basin, SW China: From the perspective of environment and energy. ACS Sustainable Chemistry & Engineering, 2020, 8(30), 11435-11445.
[22]Zhao Peng, Xie Lingzhi, Ge Qi, Zhang Yao, Liu Jun, He Bo. Numerical study of the effect of natural fractures on shale hydraulic fracturing based on the continuum approach. Journal of Petroleum Science and Engineering, 2020, 189, 107038.
[23]Liu Jun, Xie Lingzhi, Yao Yanbin, Gan Quan, Zhao Peng*, Du Longhuan. Preliminary study of influence factors and estimation model of the enhanced gas recovery stimulated by carbon dioxide utilization in shale. ACS Sustainable Chemistry & Engineering, 2019, 7(24), 20114-20125.
[24]Zhao Peng, Xie Lingzhi, He Bo, Zhang Yao. Experimental study of rock-sheds constructed with PE fibres and composite cushion against rockfall impacts. Engineering Structures, 2018, 177, 175-189.
[25]Zhao Peng, Xie Lingzhi, Li Liangpu, Liu Quan, Yuan Song. Large-scale rockfall impact experiments on a RC rock-shed with a newly proposed cushion layer composed of sand and EPE. Engineering Structures, 2018, 175: 386-398.
[26]王静峰, 赵鹏*, 袁松, 黎良仆, 谢凌志. 复合垫层钢棚洞抵抗落石冲击性能研究. 土木工程学报, 2018, 51(2), 7-13.
[27]赵鹏, 谢凌志, 熊伦. 无煤柱开采条件下煤岩体支承压力的数值模拟. 煤炭学报, 2011, 36(12), 2029-2034.
[28]赵鹏, 谢凌志, 杨春和, 郭印同. 基于弥散式裂缝模型的水力压裂研究. 岩石力学与工程学报, 2015, 34(1), 2593-2600.
◎专利
(1)一种基于干热岩破裂面分形特征的岩石力学特性预测方法,ZL202410119664.3
(2)一种基于页岩气压裂井下裂缝实时三维拟合系统及方法,ZL202410900416.2
(3)一种干热岩天然裂缝三维构建方法,ZL202410059437.6
(4)一种裂缝性气藏压裂反排用加压结构,ZL202410016049.X
(5)一种油气井套管变形防治方法,ZL202310773447.1
◎行政职务及社会职务
(1)油气地质与采收率青年编委
(2)Rock Mechanics Bulletin青年编委
(3)断块油气田青年编委