Frontiers of Engineering Management >
Strategic analysis of China’s geothermal energy industry
Received date: 11 Dec 2019
Accepted date: 12 Mar 2020
Published date: 15 Sep 2021
Copyright
China is an early user of geothermal energy, and its direct use ranks first in the world. Recent national strategies and policies have enabled China’s geothermal energy industry to enter a new era with important development opportunities. This paper investigates the strengths, weaknesses, opportunities, and threats (SWOT) to China’s geothermal energy industry from political, economic, social, and technological (PEST) perspectives. SWOT–PEST analysis indicates that the resources, market, and technological foundation exist for the large-scale development of China’s geothermal energy industry. However, it experiences constraints, such as unclear resource distributions, incomplete development of government regulations, incomplete implementation of national policies, unclear authority between governmental administrative systems, and lack of uniform technical standards and codes. Therefore, future development strategies have been proposed to provide technical support and policy tools for geothermal energy development. The recommendations to ensure its healthy and sustainable development include improving resource exploration, rationalizing administration systems, enhancing policy guidance and financial support, and cultivating geothermal talent.
Key words: geothermal energy; strategic analysis; SWOT–PEST; policy; administration
Hao GONG , Baicun WANG , Haijun LIANG , Zuoxian LUO , Yaofeng CAO . Strategic analysis of China’s geothermal energy industry[J]. Frontiers of Engineering Management, 2021 , 8(3) : 390 -401 . DOI: 10.1007/s42524-020-0106-4
| 1 |
Chang S, Zhuo J, Meng S, Qin S, Yao Q (2016). Clean coal technologies in China: Current status and future perspectives. Engineering, 2(4): 447–459
|
| 2 |
Cui Y, Zhu J, Twaha S, Chu J, Bai H, Huang K, Chen X, Zoras S, Soleimani Z (2019). Techno-economic assessment of the horizontal geothermal heat pump systems: A comprehensive review. Energy Conversion and Management, 191: 208–236
|
| 3 |
Duan J (2013). Guiding opinions on promoting the development and utilization of geothermal energy released. Urban Geology, 8(1): 17 (in Chinese)
|
| 4 |
Duo J, Wang G L, Zheng K Y (2017). Research on the Strategy of Development and Utilization of Geothermal Resources in China. Beijing: Science Press (in Chinese)
|
| 5 |
Feng Z, Zhao Y, Zhou A, Zhang N (2012). Development program of hot dry rock geothermal resource in the Yangbajing Basin of China. Renewable Energy, 39(1): 490–495
|
| 6 |
Geller H (2012). Energy Revolution: Policies for a Sustainable Future. Washington DC: Island Press
|
| 7 |
Geothermal Energy Association (2016). 2016 annual US global geothermal power production report. Geothermal Energy Association
|
| 8 |
Gong H, Luo Z, Liang H, Liu R, Wang H, Gu X, Hu J (2018). Study on the current situation and optimization of geothermal resources management in China. Ecological Economy, 34(6): 94–99 (in Chinese)
|
| 9 |
Guan X, Wei H, Lu S, Dai Q, Su H (2018). Assessment on the urbanization strategy in China: Achievements, challenges and reflections. Habitat International, 71: 97–109
|
| 10 |
Gupta A (2013). Environment & PEST analysis: An approach to the external business environment. International Journal of Modern Social Sciences, 2(1): 34–43
|
| 11 |
Ha H, Coghill K (2008). E-government in Singapore: A SWOT and PEST analysis. Asia-Pacific Social Science Review, 6(2): 103–130
|
| 12 |
Hou J, Cao M, Liu P (2018). Development and utilization of geothermal energy in China: Current practices and future strategies. Renewable Energy, 125: 401–412
|
| 13 |
Hu M (2017). Geothermal energy development and utilization of the 13th Five-Year Plan released. Petroleum Refinery Engineering, 47(3): 26 (in Chinese)
|
| 14 |
Hu Q, Zhang Y (2017). Xiong County Model leads new trends in Xiong’an new district construction. Sinopec Monthly, (4): 58–59 (in Chinese)
|
| 15 |
Huang S (2012). Geothermal energy in China. Nature Climate Change, 2(8): 557–560
|
| 16 |
Huang S (2014). Opportunity and challenges of geothermal energy development in China. Energy of China, 36(9): 4–8, 16 (in Chinese)
|
| 17 |
Jiang G, Gao P, Rao S, Zhang L, Tang X, Huang F, Zhao P, Pang Z, He L, Hu S, Wang J (2016). Compilation of heat flow data in the continental area of China, 4th ed. Chinese Journal of Geophysics, 59(8): 2892–2910 (in Chinese)
|
| 18 |
Jiang G, Hu S, Shi Y, Zhang C, Wang Z, Hu D (2019). Terrestrial heat flow of continental China: Updated dataset and tectonic implications. Tectonophysics, 753: 36–48
|
| 19 |
Kumar L, Hasanuzzaman M, Rahim N (2019). Global advancement of solar thermal energy technologies for industrial process heat and its future prospects: A review. Energy Conversion and Management, 195: 885–908
|
| 20 |
Li Y (2005). The system construction and choice of Renewable Energy Promoting Law of China. Journal of Renmin University of China, (1): 133–140 (in Chinese)
|
| 21 |
Lian J, Zhang Y, Ma C, Yang Y, Chaima E (2019). A review on recent sizing methodologies of hybrid renewable energy systems. Energy Conversion and Management, 199: 112027
|
| 22 |
Liao Z, Xiong S (2008). A new green energy source—Combustible ice. Natural Gas Technology and Economy, (2): 64–66, 95 (in Chinese)
|
| 23 |
Liu H, Yan J, Meng S, Yang Q, Yao Z, Zhu S (2019). Practice and understanding of developing new technologies and equipment for green and low-carbon production of oilfields. Frontiers of Engineering Management, 6(4): 517–523
|
| 24 |
Liu Q, Lei Q, Xu H, Yuan J (2018). China’s energy revolution strategy into 2030. Resources, Conservation and Recycling, 128: 78–89
|
| 25 |
Luo Z (2017). Some considerations about China’s geothermal industrial policy optimization reform. Petroleum & Petrochemical Today, 25(6): 6–12, 50 (in Chinese)
|
| 26 |
Mathews J, Tan H (2015). China’s Renewable Energy Revolution. Berlin: Springer
|
| 27 |
Massachusetts Institute of Technology-led Interdisciplinary Panel (2006). The future of geothermal energy: Impact of enhanced geothermal systems (EGS) on the United States in the 21st century. Geothermics, 17(5–6): 881–882
|
| 28 |
Pickton D, Wright S (1998). What’s SWOT in strategic analysis? Strategic Change, 7(2): 101–109
|
| 29 |
Wan Z, Zhao Y, Kang J (2005). Forecast and evaluation of hot dry rock geothermal resource in China. Renewable Energy, 30(12): 1831–1846
|
| 30 |
Wang B, Hong Y, Hou X, Xu Z, Wang P, Fang X, Ruan X (2015). Numerical configuration design and investigation of heat transfer enhancement in pipes filled with gradient porous materials. Energy Conversion and Management, 105: 206–215
|
| 31 |
Wang G, Zhang W, Liang J, Lin W, Liu Z, Wang W (2017). Evaluation of geothermal resources potential in China. Acta Geoscientica Sinica, 38(4): 449–459 (in Chinese)
|
| 32 |
Wang Y (1998). People’s Republic of China Mineral Resources Law. China Land, 5: 42–45 (in Chinese)
|
| 33 |
Xiao L, Zhao R (2017). China’s new era of ecological civilization. Science, 358(6366): 1008–1009
|
| 34 |
Xiong G, Zhu F, Liu X, Dong X, Huang W, Chen S, Zhao K (2015). Cyber-physical-social system in intelligent transportation. IEEE/CAA Journal of Automatica Sinica, 2(3): 320–333
|
| 35 |
Zhou J, Li P, Zhou Y, Wang B, Zang J, Meng L (2018). Toward new-generation intelligent manufacturing. Engineering, 4(1): 11–20
|
| 36 |
Zhou J, Zhou Y, Wang B, Zang J (2019). Human-cyber-physical systems (HCPSs) in the context of new-generation intelligent manufacturing. Engineering, 5(4): 624–636
|
| 37 |
Zhou Z, Liu S, Liu J (2015). Study on the characteristics and development strategies of geothermal resources in China. Journal of Natural Resources, 30(7): 1210–1221 (in Chinese)
|
| 38 |
Zou C, Zhao Q, Zhang G, Xiong B (2016). Energy revolution: From a fossil energy era to a new energy era. Natural Gas Industry B, 3(1): 1–11
|
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