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Gas hydrate stability zone in Muri coalfield, Qinghai Province, China

Published online by Cambridge University Press:  29 November 2021

Jing LI*
Affiliation:
Shanxi Institute of Energy, Jinzhong 030600, China.
Zheng YAO
Affiliation:
Shaanxi Institute of Geological Survey, Xi'an 710054, China.
Hongbo ZHAO
Affiliation:
Shanxi Institute of Energy, Jinzhong 030600, China.
Zewei WANG
Affiliation:
Hebei University of Engineering, Handan 056038, China.
*
*Corresponding author. Email: cat03510431@163.com

Abstract

The gas hydrate stability zone (GHSZ) is the essential condition for gas hydrate accumulation, which is controlled by three main factors: gas component, geothermal gradient and permafrost thickness. Based on the gas component of hydrate samples from drilling in Muri coalfield, the gas hydrate phase equilibrium curve was calculated using Sloan's natural gas hydrate phase equilibrium procedure (CSMHYD) program. Through temperature data processing of coalfield boreholes, some important data such as thickness of permafrost and geothermal gradient were obtained. The GHSZ parameters of a single borehole were calculated by programming based on the above basic data. The average thickness of GHSZ of 85 boreholes in Muri coalfield amounted to approximately 1000 m, indicating very broad space for gas hydrate occurrence. The isogram of GHSZ bottom depth drawn from single borehole data in Muri coalfield demonstrated the regional distribution characteristics of GHSZ, and identified three favourable areas of gas hydrate occurrence where the bottom of GHSZ had a burial depth >1500 m – namely, the southern part of Juhugeng Mining Area, the middle part of Duosuogongma Mining Area and the eastern part of Xuehuoli Mining Area.

Type
Articles
Copyright
Copyright © The Author(s), 2021. Published by Cambridge University Press on behalf of The Royal Society of Edinburgh

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References

7. References

Cao, D., Tianji, L. Dan, W., Tong, W., Huaijun, W. & Yulu, P. 2009. Analysis of formation conditions of natural gas hydrate in Muri Coalfield, Qinghai Province. Coal Geology of China 21, 36.Google Scholar
Cao, D., Dan, W. & Tong, W. 2010a. Formation conditions and resource prospect of natural gas hydrate in Muri coalfield, Qinghai province, China//. Bao Yunqiao ed. 2010 Conference on Energy Strategy and Technology. London: London Science Publishing Limited, 131–34.Google Scholar
Cao, D., Hongbo, S. & Junfei, S. 2010b. Coal-controlled structural styles and looking for coal resources in Muli coalfield, Northeastern Qinghai, China. Geological Bulletin of China 29, 1696–703.Google Scholar
Chen, D., Maochun, W. & Bin, X. 2005. Formation condition and distribution prediction of gas hydrate in Qinghai Tibet Plateau permafrost. Chinese Journal of Geophysics 48, 165–72.CrossRefGoogle Scholar
Chen, Y., Tie, Y. Xiaofeng, S., Junbo, Q. & Di, Y. 2020. Study on influence factors and rules of gas hydrate phase equilibrium based on Multiflash software. Journal of Chengdu University of Technology 47, 358–66.Google Scholar
Chuai, S., Wang, H. & Ning, Z. 2019. 3-D Phase equilibrium surface equation of methane hydrate considering the effect of temperature, pressure and salt concentration. Oil and Gas Chemicals 48, 4955.Google Scholar
Grassmann, S., Cramer, B. Delisle, G., Hantschel, T., Messner, J. & Winsemann, J. 2010. pT-effects of Pleistocene glacial periods on permafrost, gas hydrate stability zones and reservoir of the Mittelplate oil field, northern Germany. Mar. Pet. Geol 27, 298306.CrossRefGoogle Scholar
Graves, C. A., James, R. H. Sapart, C. J., Stott, A. W., Wright, I. C., Berndt, C., Westbrook, G. K. & Connelly, D. P. 2017. Methane in shallow subsurface sediments at the landward limit of the gas hydrate stability zone offshore western Svalbard. Geochimica et Cosmochimica Acta 198, 419–38.CrossRefGoogle Scholar
Jin, C., Dewu, Q. Zhenquan, L., Youhai, Z., Yongqin, Z., Huaijun, W., Yonghong, L., Pingkang, W. & Xia, H. 2011. Study on the characteristics of gas hydrate stability zone in the Muri permafrost, Qinghai-comparison between the modeling and drilling results. Chinese Journal of Geophysics 54, 173–81.CrossRefGoogle Scholar
Li, J., Daiyong, C., Xuqian, D. & Dan, W. Accumulation model ofnatural gas hydrate in Muliarea[J]. Journal of Liaoning Technical University(Natural Science) 2012, 31(4): 484-488.Google Scholar
Liang, W., Tongbin, Z., Zhongwei, C., Hengjie, L., Xianzhen, C. & Jixian, Z. 2018. Reservoir volume of gas hydrate stability zones in permafrost regions of China [J]. Applied Energy 225, 486500.Google Scholar
Liu, J., Rui, Y. Daidai, W., Guangrong, J. & Hui, Z. 2019. Factors affecting the thickness of gas hydrate stability zones in the Huaguang Sag, Qiongdongnan Basin. Haiyang Xuebao 41, 1325.Google Scholar
Lu, Z., Youhai, Z. Yongqin, Z., Huaijun, W., Yonghong, L., Zhiyao, J., Changling, L., Pingkang, W. & Qingmei, L. 2010. Basic geological characteristics of gas hydrates in Qilian Mountain permafrost area Qinghai province. Mineral Deposits 29, 182–91.Google Scholar
Makogon, Y. F., Holditch, S. A. & Makogon, T. Y. 2007. Natural gas-hydrates – a potential energy source for the 21st century. Journal of Petroleum Science and Engineering 56, 1431.CrossRefGoogle Scholar
Milkov, A. V. & Sassen, R. 2000. Thickness of the gas hydrate stability zone, Gulf of Mexico continental slope. Marine and Petroleum Geology 17, 981–91.CrossRefGoogle Scholar
Sloan, E. D. 1998. Clathrate hydrate of natural gases. New York: Marcel Dekker Inc.Google Scholar
Wang, A. M., Li, J., Wei, Y. C., Yang, C. W., Nie, J. & Cao, D. Y. 2020a. Gas migration for terrestrial gas hydrates in the Juhugeng mining area of Muli basin, Qilian Mountains, Northwest China. Energy Exploration & Exploitation 38, 9891013.CrossRefGoogle Scholar
Wang, L., Tao, Z. & Ze, C. 2020b. Numerical simulation study on natural gas hydrate decomposition-two phase flow. Journal of Shandong University of Science and Technology 39, 5360.Google Scholar
Wang, S., Haibin, S. & Wen, Y. 2005. The change of external conditions effects on the phase equilibrium curve of gas hydrate and the thickness of hydrate stability zone. Progress in Geophysics 20, 761–68.Google Scholar
Wang, Y., Jianzhong, Z. Gao, Q. & Jun, Z. 2018. Experimental study on the formation and phase equilibria of methane hydrate in quartz sand media. Oil and Gas Chemicals 47, 4449.Google Scholar
Wen, H., Longyi, S. Yonghong, L., Jing, L., Shaolin, Z., Wenlong, W. & Man, H. 2011. Structure and stratigraphy of the Juhugeng coal district at Muli, Tianjun County, Qinghai Province. Geological Bulletin of China 30, 1823–28.Google Scholar
Yang, D., Qingping, W. & Haikui, T. 2011. A study on Jurassic coal-bearing rock series sedimentary facies in Juhugeng Mine Area, Qinghai. Coal Geology of China 23, 1517.Google Scholar
Zhang, H., Haiqi, Z. & Youhai, Z. 2007. Gas hydrate investigation and research in China: present status and progress. Geology in China 36, 953–61.Google Scholar
Zhang, J., Wei, W. & Wen, L. 2011. Effect analysis of gas hydrates phase equilibrium and stability zones in marine bottom. Chemical Engineering & Equipment 1, 3942.Google Scholar
Zhang, L., Xuezu, X. & Wei, M. 2001. Permafrost and gas hydrates in the Qinghai-Tibet Plateau. Natural Gas Geoscience 12, 2226.Google Scholar
Zhu, Y., Yongqin, Z. Huaijun, W., Zhenquan, L. & Pingkang, W. 2009. Gas hydrates in the Qilian Mountain permafrost, Qinghai, Northwest China. Acta Geological Sinica 83, 1762–70.Google Scholar
Zhu, Y., Yongqin, Z. Huaijun, W., Zhenquan, L. & Pingkang, W. 2010. Gas hydrates in the Qilian Mountain Permafrost and their basic characteristics. Acta Geoscientica Sinica 31, 716.Google Scholar