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Australia

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Bangladesh    

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Brazil 

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Canada           

C. Gorecki, S. C. Ayash, G. Liu, J. R. Braunberger and N. W. Dotzenrod, “A comparison of volumetric and dynamic CO2 storage resource and efficiency in deep saline formations.,” International Journal of Greenhouse Gas Technologies, vol. 42, pp. 213-225, 2015.

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China 

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Y. Diao, G. Zhu, X. Li, B. Bai, Y. Wang, B. Zhang and H. Long, “An upgraded storage site model of the Shenhua CCS demonstration project,” Energy Procedia 154, pp. 94-99, 2018.

C. Vincent, S. Dai, C. Wenying, Z. Rongshu, D. Guosheng, R. Xu, T. Vangkilde-Pedersen and F. Dalhoff, “Carbon dioxide storage options for the COACH project in the Bohai Basin, China,” Energy Procedia, pp. 2785- 2792, 2010.

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H. J. Liu, P. Were, Q. Li, Y. Gou and Z. Hou, “Worldwide Status of CCUS Technologies and Their Development and Challenges in China,” Hindawi, Geofluids, 2017.

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Denmark

K. Anthonsen, C. Bernstone and H. Feldrappe, “Screening for CO2 storage sites in Southeast North Sea and Southwest Baltic Sea,” Energy Procedia, pp. 5083-5092, 2014.

Germany

K. Anthonsen, C. Bernstone and H. Feldrappe, “Screening for CO2 storage sites in Southeast North Sea and Southwest Baltic Sea,” Energy Procedia, pp. 5083-5092, 2014.

India    

British Geological Survey, “A Regional Assessment of the Potential for the CO2 Storage in the Indian Subcontinent,” IEAGHG, 2008.

Indonesia

Asian Development Bank, “Prospects for Carbon Capture and Storage in Southeast Asia,” Mandaluyong City, Philippines, 2013.

CO2CRC Technologies Pty Ltd, “Assessment of the capture and storage potential of CO2 co-produced with natural gas in South-East Asia,” Asia- Pacific Economic Cooperation, Sydney, Australia, 2010.

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U. P. Iksandar, Usman and S. Sofyan, “Ranking of Indonesia sedimentary basin and storage capacity estimates for CO2 geological storage,” Energy Procedia, vol. 37, pp. 5172-5180, 2013.

Japan

S. Tanaka, H. Koide and A. Sasagawa, “Possibility of Underground CO2 Sequestration in Japan.,” Energy Convers. Mgmt, vol. 36, pp. 527-530, 1995.

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T. Ogawa, S. Nakanishi, T. Shidahara, T. Okumura and E. Hayashi,“Saline-aquifer CO2 Sequestration in Japan-Methodology of Storage Capacity Assessment,” International Journal of Greenhouse Gas Control, vol. 5, no. 2, p. 318–326, 2011.

M. Abe, S. Saito, D. Tanase, Y. Sawada, Y. Hirama and Y. Motoyama, “CCS Large-scale Demonstration in Japan,” Energy Procedia, vol. 37, pp. 6326-6334, 2013.

T. Hashimoto, S. Hiramatsu, T. Yamamoto, H. Takano, M. Mizuno and H. Miida, “Evaluation of CO2 Aquifer storage capacity in the vicinity of a large emission area in Japan: Case history of Osaka Bay,” Energy Procedia, vol. 1, pp. 2701-2708, 2009.

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Y. Sawada, J. Tanaka, C. Suzuki, D. Tanase and Y. Tanaka, “Tomakomai CCS Demonstration Project of Japan, CO2 Injection in Progress,” Energy Procedia, vol. 154, pp. 3-8, 2018.

Malaysia

R. Junin and D. Z. Abang Hasbollah, “CO2 Storage Capacity Assessment of Deep saline Aquifers in Malaysia,” in World Academy of Science, Engineering and Technology, WASET 2016, London, U.K., 2016.

Mexico

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B. Heras Cruz and J. Mota Nieto, “Development of Mexico’s CCUS Regulatory Framework,” in 14th International Conference on Greenhouse Gas Control Technologies, GHGT-14, Melbourne, 2018.

Norway           

Norwegian Petroleum Directorate, “CO2 Storage Atlas – Norwegian Continental Shelf,” NPD, 2014. [55] Equinor, “Climate data,” [Online]. Available: https://sustainability.equinor.com/climate-tables. [Accessed 24 February 2021].

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H. M. Nilsen, K.-A. Lie and O. Andersen, “Analysis of CO2 trapping capacities and long-term migration for geological formations in the Norwegian North Sea using MRST-co2lab,” Computers & Geosciences, pp. 15-26, 2015.

A. E. Lothe, B. Emmel, A. Grøver and P. E. Bergmo, “CO2 storage and modelling and capacity estimation for the Trøndelag Platform, offshore Norway – using a basin modelling approach,” Energy Procedia, pp. 3648- 3657, 2014.

Norwegian Petroleum, “Emissions to Air,” 2020. [Online]. Available:https://www.norskpetroleum.no/en/environment-andtechnology/emissions-to-air/.

Pakistan         

British Geological Survey, “A Regional Assessment of the Potential for the CO2 Storage in the Indian Subcontinent,” IEAGHG, 2008.

South Korea

J.-Y. Park, S. Lee, J.-H. Kihm, J.-M. Kim and Y. I. Lee, “Probabilistic evaluation of multi-fluid-phase carbon dioxide storage capacities of saline formations in the Pohang Basin, Korea using three-dimensional geologic modeling and grid-based Monte Carlo simulation,” International Journal of Greenhouse Gas Control, vol. 79, pp. 289-312, 2018.

A.-R. Kim, G.-C. Cho and T.-H. Kwon, “Site characterization and geotechnical aspects on geological storage of CO2 in Korea,” Geosciences Journal, vol. 18, no. 2, pp. 167-179, 2014.

G. Lee, B. Lee, H.-J. Kim, K. Lee and M. Park, “The geological CO2 storage capacity of the Jeju Basin, offshore southern Korea, estimated using the storage efficiency.,” International Journal of Greenhouse Gas Control, pp. 22-29, 2014.

D. Huh and D. Yoo, “CO2 Geological Storage Potential in Korea,” Energy Procedia, pp. 4881-4888, 2011.

J. Garthwaite, “Stanford Earth,” 23 May 2019. [Online]. Available: https://earth.stanford.edu/news/lessons-pohang-solving-geothermalenergys- earthquake-problem#gs.tq7ev4. [Accessed 16 February 2021].

Y. C. Park, Y. J. Shinn, Y. S. Lee and B. I. Choi, “Estimation of CO2 Storage Capacity in a Depleted Gas Field on the Korean Continental Shelf.,” in 14th International Conference on Greenhouse Gas Control Technologies, GHGT-14., Melbourne, Australia, 2018.DOE, “Carbon Sequestration Atlas of the US and Canada,” NETL, 2007.

J. Park, M. Yang, S. Kim, M. Lee and S. Wang, “The scCO2 storage and sealing capacity of the Janggi Basin in Korea; based on laboratory scale experiments”. Preprints (www.preprints.org).

C. Jun, M. Kim and H. Shin, “Optimization of well placement and operating conditions for various well patterns in CO2 sequestration in the Pohang Basin, Korea,” International Journal of Greenhouse Gas Control, vol. 90, 2019.

S. K. Hong, H. Lee, K. Egawa, T. Choi, M. Lee, K.-C. Yoo, J.-H. Kihm, Y. I. Lee and J.-M. Kim, “Preliminary evaluation for carbon dioxide storage capacity of the Chungnam, Taebacksan, Mungyeong and Honam basins,” Journal of the Geological Society of Korea, vol. 45, no. 5, pp. 449-462, 2009.

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K. Egawa, S. Hong, H. Lee, T. Choi, M. Lee, J. Kang, K. Yoo, J. Kim, Y. Lee, J. Kihm and J. Kim, “Preliminary evaluation of geological storage capacity of carbon dioxide in sandstones of the Sindong Group, Gyeongsang Basin (Cretaceous).,” Journal of the Geological Society of Korea, vol. 45, pp. 463-472, 2009.

S. Wang, J. Kim and M. Lee, “Measurement of the sCO2 storage ratio for the CO2 reservoir rocks in Korea,” Energy Procedia, vol. 97, pp. 342-347, 2016.

H. Kim, “Perspectives of Geological CO2 Storage in South Korea to Cope with Climate Change,” Sustainability, vol. 10, 2018.

Sri Lanka

British Geological Survey, “A Regional Assessment of the Potential for the CO2 Storage in the Indian Subcontinent,” IEAGHG, 2008.

UK

European Parliament, “Directive 2009/31/EC on the geological storage of carbon dioxide,” 2009. [Online]. Available: https://eurlex. europa.eu/LexUriServ/LexUriServ.do?uri=OJ:L:2009:140:0114:0135:E N:PDF. [Accessed 15 02 2021].

USA

NETL, “Carbon Storage Atlas V,” US Department of Energy, 2015.

A. Goodman, A. Hakala, G. Bromhal, D. Deel, T. Rodosta, S. Fraily, M. Small, D. Allen, V. Romanov, J. Fazio, N. Huerta, D. McIntyre, B. Kutchko and G. Guthrie, “U.S. DOE methodology for development of geologic storage potential for carbon dioxide at national and regional scale.,” Int. J Greenhouse Gas Control, vol. 5, no. 4, pp. 952-965, 2011.

United States Geological Survey, “Sedimentary Basins – CGG Veritas – Extract from Global CCS Institute,” United States Geological Survey, 2017.