(26) 一种井壁稳定效果评价实验装置及方法，郭明义;安莹慧;李铠君;李颖;韦昭杰，中国发明专利，2024， ZL2022 1 0978068.1。

(25) 用于深部钻井孔隙封堵和润湿调控的纳米乳液及其制备, 郭明义，李颖，王茂森，安莹慧，曹品鲁，博坤，中国发明专利，2024，ZL202211299366.4。

(24) Synergistic effects of potassium alginate and silicates co-inhibition performance in shale hydration, Zhaojie Wei, Maosen Wang, Wenjun Shan, Mingyi Guo, Ying Li, Wenjing Qin, Kaijun Li, Yinghui An, Kun Bo*, Journal of Molecular Liquids, 2024, 393, 123538-123549.

(23) A novel oil-in-water nanoemulsion as a high-temperature plugging agent for wellbore wettability alteration and strengthening, Ying Li, Maosen Wang, Zhaojie Wei, Yinhui An, Wenjing Qin, Kun Bo, Pinlu Cao*, Mingyi Guo*, Journal of Molecular Liquids, 2023, 384, 122273-122282.

(22) In situ shale wettability regulation using sophisticated nanoemulsion to maintain wellbore stability in deep well drilling, Ying Li, Maosen Wang, Yinghui An, Kaijun Li, Zhaojie Wei, Kun Bo, Pinlu Cao, and Mingyi Guo^*, Langmuir, 2022, 38 (41), 12539-12550.

(21)  Sodium alginate as an eco-friendly rheology modifier and salt-tolerant fluid loss additive in water-based drilling fluids, Zhaojie Wei, Maosen Wang, Ying Li, Yinghui An, Kaijun Li, Kun Bo and Mingyi Guo^*, RSC Adv., 2022, 12, 29852.

(20)  Regulating the oxidative assisted pyrolysis of Huadian oil shale by preheating temperature and oxygen flow rate,  Shaotao Xu, Youhong Sun^*, Wei Guo, Qinchuan Yang, Qiang Li, Mingyi Guo, Fengtian Bai, Chaofan Zhu, Sunhua Deng^*, Energy, 2023, 262, 125602.

(19)  Application of hybrid silicate as a film-forming agent in high temperature water-based drilling fluid, Ying Li, Maosen Wang, Xianfeng Tan, Yinghui An, Huanan Liu, Ke Gao, Mingyi Guo^*, ACS Omega, 2021, 6, 31, 20577–20589.

(18) Effects of Associated Minerals on the Co-Current Oxidizing Pyrolysis of Oil Shale in a Low-Temperature Stage，Qinchuan Yang, Mingyi Guo, and Wei Guo*，ACS Omega，2021, 6, 37, 23988-23997.

(17)  A Zwitterionic Copolymer as Rheology Modifier and Fluid Loss Agents for Water-Based Drilling Fluids, Xianfeng Tan, Longchen Duan^*, Weichao Han, Ying Li and Mingyi Guo^*, Polymers, 2021, 13, 3120.

(16)  一种有机-无机复合硅酸盐耐高温成膜钻井液体系，郭明义，李颖，韩炜超、谭现锋、博坤、曹品鲁，中国发明专利，2021，ZL201910151350.0。

(15)  Effects of composition and pore evolution on thermophysical properties of Huadian oil shale in retorting and oxidizing pyrolysis, fuel, Shaotao Xu, Youhong Sun^⁎, XiaoshuLü, Qinchuan Yang, Qiang Li, Zhendong Wang, Mingyi Guo^⁎, Fuel, 2021, 305, 121565.

(14)  桦甸油页岩有氧热解反应及其产物分布，孙友宏，徐绍涛，杨秦川，赖城，郭明义，中国石油大学学报，2021，45（2）149-156.

(13)  Thermal Degradations and Processes of Four Kerogens via Thermogravimetric−Fourier-Transform Infrared: Pyrolysis Performances, Products, and Kinetics, Fengtian Bai, Yumin Liu, Cheng Lai, Youhong Sun, Junxian Wang, Pingchang Sun, Linfu Xue, Jinmin Zhao, and Mingyi Guo^*, Energy & Fuels 2020, 34, 2969−2979.

(12)  Characteristics and Kinetics of Huadian Oil Shale Pyrolysis via Non-isothermal Thermogravimetric and Gray Relational Analysis, Fengtian Bai, Youhong Sun, Yumin Liu^*, Mingyi Guo^*, Jinmin Zhao, Combustion Science and Technology, 2020, 192 (3), 471-485.

(11)  Characteristics of low temperature co-current oxidizing pyrolysis of Huadian oil shale, Wei Guo, Qinchuan Yang, Youhong Sun, Shaotao Xu, Shijie Kang, Cheng Lai, Mingyi Guo^*, Journal of Analytical and Applied Pyrolysis, 2020, 146, 104759.

(10)  耐240℃高温水基成膜钻井液的室内研究, 李颖，谭现锋，韩炜超，李铠君，郭明义,钻井液与完井液，2019, 36 (5), 548-554。

(9)  甲基硅酸盐抑制粘土水化性能及机理，韩炜超，李颖，谭现锋，郭明义，徐会文，探矿工程（岩土钻掘工程）, 2018, 45(11), 19-23。

(8)  Colloidal Carbon Beads as Lubricant Additives in Water Based Drilling Fluid, Youhong Sun, Xianfeng Tan, Huanan Liu, Huiwen Xu, Qingnan Meng, Mingyi Guo^*, International Journal of Earth Sciences and Engineering, 2017,10(04), 787-792.

(7)  Evaluation of the porous structure of Huadian oil shale during pyrolysis using multiple approaches, Fengtian Bai, Youhong Sun^*, Yumin Liu, Mingyi Guo^*, Fuel, 2017,187, 1-8.

(6)  Kinetic investigation on partially oxidized Huadian oil shale by thermogravimetric analysis, Fengtian Bai, Youhong Sun^*, Yumin Liu, Baochang Liu, Mingyi Guo^*, Xiaoshu Lv, Wei Guo, Qiang Li, Chuanbin Hou, Qiuwen Wang, Oil Shale,2014, 31 377-393.

(5) Kinetic study on the pyrolysis behavior of Huadian oil shale via non-isothermal thermogravimetric data, Fengtian Bai, Wei Guo^*, Xiaoshu Lü, Yumin Liu, Mingyi Guo, Qiang Li, Youhong Sun^*, Fuel, 2015, 146, 111-118.

(4) Thermal and kinetic characteristics of pyrolysis and combustion of three oil shales, Fengtian Bai, Youhong Sun^*, Yumin Liu, Qiang Li, Mingyi Guo, Energy Conversion and Management, 2015, 97, 374-381.

(3) Kinetic study of Huadian oil shale combustion using a multi-stage parallel reaction model, Youhong Sun, Fengtian Bai^*, Xiaoshu Lü, Chunxia Jia, Qing Wang^*, Mingyi Guo, Qiang Li, Wei Guo^*, Energy, 2015, 82, 705-713.

(2) A Novel Energy-Efficient Pyrolysis Process: Self-pyrolysis of Oil Shale Triggered by Topochemical Heat in a Horizontal Fixed Bed, You-Hong Sun^*, Feng-Tian Bai^*, Xiao-Shu Lü, Qiang Li, Yu-Min Liu, Ming-Yi Guo, Wei Guo, Bao-Chang Liu, Scientific Reports, 2015, 5, 8290.

(1) Characterization of the oil shale products derived via topochemical reaction method, Youhong Sun, Fengtian Bai*, Baochang Liu, Yumin Liu, Mingyi Guo*, Wei Guo, Qiuwen Wang, Xiaoshu Lü, Fang Yang, Yang Yang, Fuel, 2014,115, 338-346.