学术论文

  • Zhang, F., Tang, J., Zhou, J., Liu, Y., Li, J., Zeng, Y., Zhao, Z., Zhang, J., Sun, Z., Hu, W. 2026. Securing CO₂ Storage in Fractured Reservoirs: Intelligent Characterization of Critical Natural Fracture Pathways.Fuel. 406 (Part B): 136915. (IF=7.5,SCI2区TOP,学生1作,导师通讯)
  • Ma, D., Wu, Y., Tang, J., Hao, Y., Pu, H., & Yuan, H. (2025). Comparison of machine learning-based breakdown pressure prediction and initiation criteria in hydraulic fracturing testing. International Journal of Applied Mechanics, 17(1), 2450122.(IF=2.6,SCI4区)
  • Zhang, Z., Tang, J., Fan, B., Zhao, X., Jin, F., Chen, C., ... & Yang, J. (2024). An intelligent lithology recognition system for continental shale by using digital coring images and convolutional neural networks. Geoenergy Science and Engineering, 239, 212909.(IF=4.6,SCI2区,学生1作,导师通讯)
  • Zhao, W., Liu, T., Tang, J., & Zhang, J. (2023). Estimating additional resistivity by permeability in brine-saturated sandstones. Petroleum Geoscience, 29(3), petgeo2022-067.(IF=2.1,SCI4区)
  • Tang, J., Fan, B., Xiao, L., Tian, S., Zhang, F., Zhang, L., & Weitz, D. (2021). A new ensemble machine-learning framework for searching sweet spots in shale reservoirs. SPE Journal, 26(01), 482-497.(IF=3.0,SCI3区)
  • Tang, J., Ehlig-Economides, C., Fan, B., Cai, B., & Mao, W. (2019). A microseismic-based fracture properties characterization and visualization model for the selection of infill wells in shale reservoirs. Journal of Natural Gas Science and Engineering, 67, 147-159.(IF=5.9,SCI2区)
  • Tang, J., Zhang, M., Guo, X., Geng, J., & Li, Y. (2024). Investigation of creep and transport mechanisms of CO₂ fracturing within natural gas hydrates. Energy, 300, 131214.(IF=9.4,SCI1区TOP)
  • Tang, J., Zhang, Z., Xie, J., Meng, S., Xu, J., Ehlig-Economides, C., & Liu, H. (2024). Re-evaluation of CO₂ storage capacity of depleted fractured-vuggy carbonate reservoir. The Innovation Energy, 1(2), 100019-1.(IF=-)
  • Li, Y., Peng, G., Tang, J., Zhang, J., Zhao, W., Liu, B., & Pan, Y. (2023). Thermo-hydro-mechanical coupling simulation for fracture propagation in CO₂ fracturing based on phase-field model. Energy, 284, 128629.(IF=9.0,SCI1区TOP)
  • Zhang, Z., Tang, J., Zhang, J., Meng, S., & Li, J. (2024). Modeling of scale-dependent perforation geometrical fracture growth in naturally layered media. Engineering Geology, 336, 107499.(IF=8.4,SCI1区TOP,学生1作,导师通讯)
  • Li, Y., Jiang, X., Tang, J., & Liu, B. (2024). Simulation study of acid fracturing initiation with consideration of rock mechanics parameter variations. Rock Mechanics and Rock Engineering, 57(8), 5743-5761.(IF=6.6,SCI1区TOP)
  • 孙龙德, 刘合, 朱如凯, 崔宝文, 雷征东, 孟思炜, & 汤继周. (2023). 中国页岩油革命值得关注的十个问题. 石油学报, 44(12), 2007-2019.(中文核心)
  • 汤继周, 王小华, 杜现飞, 马兵, & 张丰收. (2023). 扇形井网体积压裂地质工程一体化参数优化方法. 石油勘探与开发, 845-852.(中文核心)
  • 汤继周, 张卓, 张丰收, 李玉伟, & 刘堂晏. (2023). 陆相页岩储层水平井无限级压裂工艺优化. 岩石力学与工程学报, 42(9), 2096-2108.(中文核心)
  • Cong, Z., Li, Y., Tang, J., Martyushev, D. A., & Yang, F. (2022). Numerical simulation of hydraulic fracture height layer-through propagation based on three-dimensional lattice method. Engineering Fracture Mechanics, 264, 108331.(IF=5.4,SCI2区)
  • Zhao, W., Hu, F., Tang, J., Liu, T., & Li, C. (2022). An approach to calculate bound water saturation by NMR logging spectral coefficient method. Acta Geophysica, 70(2), 525-535.(IF=2.3,SCI4区)
  • Xie, J., Tang, J., Yong, R., Fan, Y., Zuo, L., Chen, X., & Li, Y. (2020). A 3-D hydraulic fracture propagation model applied for shale gas reservoirs with multiple bedding planes. Engineering Fracture Mechanics, 228, 106872.(IF=4.4,SCI2区)
  • Li, Y., Zhao, Y., Tang, J., Zhang, L., Zhou, Y., Zhu, X., ... & Chen, M. (2020). Rock damage evolution model of pulsating fracturing based on energy evolution theory. Energy Science & Engineering, 8(4), 1050-1067.(IF=4.1,SCI4区)
  • Tang, J., Wu, K., Zuo, L., Xiao, L., Sun, S., & Ehlig–Economides, C. (2019). Investigation of rupture and slip mechanisms of hydraulic fractures in multiple-layered formations. SPE Journal, 24(05), 2292-2307.(IF=3.4,SCI3区)
  • Tang, J., Li, J., Tang, M., Du, X., Yin, J., Guo, X., ... & Xiao, L. (2019). Investigation of multiple hydraulic fractures evolution and well performance in lacustrine shale oil reservoirs considering stress heterogeneity. Engineering Fracture Mechanics, 218, 106569.(IF=4.4,SCI2区)
  • Tang, J., Wu, K., Zeng, B., Huang, H., Hu, X., Guo, X., & Zuo, L. (2018). Investigate effects of weak bedding interfaces on fracture geometry in unconventional reservoirs. Journal of Petroleum Science and Engineering, 165, 992-1009.(IF=3.7,SCI2区TOP)

发明专利&软著

  • 汤继周;司维;李柠;商珞然,一种生物改性压裂支撑剂及其制备方法和应用
  • 汤继周;李玉伟;卢蔚;耿建华;靳少博,一种基于变分自编码器的岩石裂缝信息识别方法及系统,2025-03-21,中国,ZL202210595664.1
  • 汤继周;李柠;杨积忠;郑文山;商珞然;裴颢,利用钻进取心与单细胞测序的多源矿产资源评价方法,2024-11-01,中国,ZL202410016216.0
  • 汤继周;张卓;陈伟华;魏志鹏,一种重复压裂工艺优化方法及系统,2024-08-20,中国,ZL202311007613.3
  • 汤继周;张敏;李玉伟;王涛;王金伟;赵峦啸;魏志鹏;姜兴文,基于测井数据的枯竭砂岩型储气库注采岩层可压性评价方法,2024-07-16,中国,ZL202410128524.2
  • 汤继周;张敏;范宇;郭旭洋;耿建华;李玉伟,考虑蠕变效应的CO₂压裂天然气水合物导流能力评价方法,2024-05-14,中国,ZL202311247550.9
  • 汤继周;付亮;曾闽山,页岩气藏多簇水力裂缝同步竞争扩展数值模拟方法及系统,2024-03-12,中国,ZL202310221651.2
  • 汤继周;尹俊;张丰收;赵峦啸,一种研究水力裂缝在层状介质中扩展规律的平台及方法,2022-03-29,中国,ZL202110703098.7
  • 汤继周,李佳宇,卢笑语,张卓,基于标签噪声学习的复杂岩性图像智能识别软件V1.0,2024SR0256828
  • 汤继周,李玉伟,张敏,姜兴文,枯竭砂岩型储气库注采储层可压性评价软件V1.0,2024SR0267922
  • 汤继周,张敏,卢笑语,考虑蠕变和渗流特性的CO₂压裂开采天然气水合物计算软件V1.0,2024SR0047832
  • 汤继周,孙大钊,张卓,离散裂缝网络智能建模软件V1.0,2024SR1671929

著作

  • 汤继周,李玉伟,陈胜男.人工智能基础理论与应用——能源矿业领域[M].北京:科学出版社,2024.ISBN 9787030766182.