[1] Cheng, Y., Wang, C., Da, W., Kong, Y., & Hu, X. (2023). Anatomy of the convective geothermal system from geophysical and hydrochemical data: A case study from the Changshou geothermal field, South China. Geophysics, 88(5), WB1–WB10.

[2] Cheng, Y., Hu, X., Kong, Y., Dong, Y., Guo, J., Wang, L., & Wang, J. (2022). Imaging acidic contaminants in a confined aquifer using electromagnetic geophysical method constrained by hydrochemical data. Journal of Hydrology, 609, 127704.

[3] Cheng, Y., Kong, Y., Wang, Z., Huang, Y., & Hu, X. (2022). Crustal Electrical Structure of the Ganzi Fault on the Eastern Tibetan Plateau: Implications for the Role of Fluids in Earthquakes. Remote Sensing, 14(13), 2990.

[4] Cheng, Y., Hu, X., Han, B., Li, Y., Kong, Y., & Tang, J. (2022). Magnetotelluric Evidence for Lithospheric Alteration Beneath the Wuyi-Yunkai Orogen: Implications for Thermal Structure of South China. Geochemistry, Geophysics, Geosystems, 23(11), e2022GC010456.

[5] Cheng, Y., Pang, Z., Kong, Y., Chen, X., & Wang, G. (2022). Imaging the heat source of the Kangding high-temperature geothermal system on the Xianshuihe fault by magnetotelluric survey. Geothermics, 102, 102386.

[6] Cheng, Y., Pang, Z., Di, Q., Chen, X., & Kong, Y. (2021). Three-dimensional resistivity structure in the hydrothermal system beneath Ganzi Basin, eastern margin of Tibetan Plateau. Geothermics, 93, 102062.

[7] Cheng, Y., Han, B., Li, Y., Guo, J., & Hu, X. (2021). Lithospheric electrical structure beneath the Cathaysia Block in South China and its tectonic implications. Tectonophysics, 814, 228981.

[8] Cheng, Y., Tang, J., Chen, X., Dong, Z., & Wang, L. (2019). Crustal structure and magma plumbing system beneath the Puer Basin, southwest China: Insights from three-dimensional magnetotelluric imaging. Tectonophysics, 763, 30–45.

[9] 程远志, 韩波, 孔彦龙, 胡祥云. (2023). 青藏高原东缘甘孜断裂带地壳电性结构与孕震构造. 地球物理学报, 66(8): 3273-3289.

[10] 程远志, 汤吉, 蔡军涛, 陈小斌, 董泽义, 汪利波. (2017). 青藏高原东缘川滇构造区深部电性结构特征. 地球物理学报, 60(6): 2425-2441.

[11] 程远志, 汤吉, 邓琰, 董泽义. (2016). 云南景谷MS6.6地震震源区深部电性结构及其孕震环境. 地震地质, 38(2): 352-369.

[12] 程远志，汤吉, 陈小斌, 董泽义, 肖骑彬, 汪利波. (2015). 南北地震带南段川滇黔接壤区电性结构特征和孕震环境. 地球物理学报, 58(11): 3965-3981.

[13] Li, Y., Luo, J., Tian, J., Cheng, Y., Pang, Z., Huang, T., & Fan, Y. (2023). Formation of the hydrothermal system from granite reservoir for power generation in igneous rock areas of South China. Geothermics, 110, 102673.

[14] Huang, Y., Kong, Y., Cheng, Y., Zhu, C., Zhang, J., & Wang, J. (2023). Evaluating the long-term sustainability of geothermal energy utilization from deep coal mines. Geothermics, 107, 102584.

[15] Luo, J., Li, Y., Tian, J., Cheng, Y., Pang, Z., & Gong, Y. (2022). Geochemistry of geothermal fluid with implications on circulation and evolution in Fengshun-Tangkeng geothermal field, South China. Geothermics, 100, 102323.

[16] Wang, K., Hua, C., Ren, L., Kong, Y., Sun, W., Pan, S., Cheng, Y., Huang, Y., Tian, F., Zhang, W., Qin, D., Ma, F., Wang, J., & Dong, Y. (2022). Geochemical and Isotopic Characteristics of Two Geothermal Systems at the Nanpu Sag, Northern Bohai Bay Basin. Frontiers in Earth Science, 10,844605.

[17] Huang, Y., Cheng, Y., Ren, L., Tian, F., Pan, S., Wang, K., Wang, J., Dong, Y., & Kong, Y. (2022). Assessing the Geothermal Resource Potential of an Active Oil Field by Integrating a 3D Geological Model with the Hydro-Thermal Coupled Simulation. Frontiers in Earth Science, 9,9787057.

[18] Li, Y., Tian, J., Cheng, Y., Jiang, G., Zhang, Yi., Chen, K., Zhonghe, P., & Pang, Z. (2021). Existence of High Temperature Geothermal Resources in the Igneous Rock Regions of South China. Frontiers in Earth Science, 9, 728162.

[19] Kong, Y., Pan, S., Ren, Y., Zhang, W., Wang, K., Jiang, G., Cheng, Y., Sun, W., Zhang, C, Hu, S. & He, L. (2021) Catalog of Enhanced Geothermal Systems Based on Heat Sources, Acta Geologica Sinica (English Edition), 95, 6, 1882–1891.

第一发明人授权发明专利:

1.程远志等，ZL202310771135.7. 中国发明专利. 2023.

2.程远志等，ZL202310927255.1. 中国发明专利. 2023.

3.程远志等，特许7421201号. 日本发明专利. 2024.

4.程远志等，特许7495769号. 日本发明专利. 2024.