AUTHORS: Ahmed Kiani

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ABSTRACT: Methane hydrates are present in substantial quantities in Northeast Asia and have the potential to disrupt global energy markets once economical extraction methods are identified and developed. Any Northeast Asian country that is able to exploit its methane hydrate resources will potentially alter its need for hydrocarbon imports. This would greatly impact future energy trade relations between Northeast Asia and Organization of the Petroleum Exporting Countries participants and could result in a shift from a broader bilateral energy trade relationship into a narrow one. Demand would decrease and hydrocarbon price fluctuations would affect revenue streams as well as international trade partnerships. In this study, we attempt to present a conceptual operational research cost model for methane hydrate integration into the energy mix in the Northeast Asian countries. Our approach takes into account key parameters including the volume of estimated reserves to minimize the cost per unit of methane hydrate in upstream processes while considering natural gas accounting as a reference point, in a reservoir dynamics-based analysis under market constraints. Finally, we propose policy recommendation based on our analysis

KEYWORDS: Gas Hydrates, North East Asia, Activity Report, Trade Partnerships, Price Breakdown, Policy Recommendations

REFERENCES:

[1] Emergency response of IEA Countries: Japan, Oil & Gas Security, 2013.

[2] The gas hydrate opportunity: Exploration and production, Luxresearch, 2014.

[3] Asia/World Energy Outlook: Analysis of lowgrowth scenarios for China and India and the climate change issue, The Institute of Energy Economics (IEE), Japan, 2014.

[4] Energy supply security, International Energy Agency (IEA), 2014.

[5] Emergency response systems of IEA partner countries: China, Energy Supply Security, 2014.

[6] Petroleum and other liquids, United States Energy Information Administration (USEIA), 2012.

[7] Research consortium on developing methane hydrate resources, MH21, 2008.

[8] Energy resource potential of methane hydrate, An introduction to the science and energy potential of a unique resource, National Energy Technology Laboratory (NETL), U.S. Department of Energy, 2011.

[9] Y. C. Beaudoin, W. Waite, R. Boswell, S. R. Dallimore, Frozen Heat: A UNEP global outlook on methane gas hydrates, Vol. 1 and 2, United Nations Environment Programme (UNEP), GRID-Arendal, 2014.

[10] R. A. Partain, Avoiding Epimetheus: Planning ahead of the commercial development of offshore methane hydrates, Sustainable Development Law & Policy, Vol. 15, No. 1, 2015, pp. 16-25.

[11] Global Trade Information Services (GTIS), World Trade Atlas, 2014.

[12] T. Callen, R. Cherif, F. Hasanov, A. Hegazy, P. Khandelwal, Economic diversification in the GCC: Past, present and future, Institute for Capacity Development and Middle East and Central Asia Department, International Monetary Fund (IMF), 2014.

[13] Shale Gas – A global perspective, KPMG Global Energy Institute, KPMG, 2011.

[14] Annual energy outlook 2015 with projections to 2040, United States Energy Information Administration (USEIA), 2015.

[15] Rystad Energy Research and Analysis, 2015.

[16] NRL Review: Methane hydrate, United States Naval Research Laboratory (NRL), 2013.

[17] P. Folger, Gas Hydrates: Resource and hazard, CRS Report for U.S. Congress, 2010.

[18] Natural Gas hydrates – Vast resources, uncertain future, United States Geological Survey (USGS), 2001.

[19] C. D. Ruppel, Methane hydrates and the future of natural gas, MITEI Gas Report, Supplementary paper on Methane Hydrates, US Geological Survey (USGS), 2011.

[20] C. D. Ruppel, T. S. Collett, Geological studies of methane hydrates reveal reserves with potential, Energy Focus, Fall edition, 2013, pp. 202-204.

[21] V. Alexiades, Methane hydrate formation and dissociation, Electronic Journal of Differential Equations, Conference, Vol. 17, 2009, pp. 1- 11.

[22] R. Boswell, Is Gas Hydrate energy within reach?, Science, Vol. 325, 2009, pp. 957-958.

[23] Enhanced Oil Recovery, Shell Technology, 2015.

[24] S. Thomas, Enhanced oil recovery – An overview, Oil & Gas Science and Technology, Vol. 63, 2008, pp. 9-19.

[25] J. Gabitto, M. Barrufet, Gas Hydrates Research Program: An international review, 2010.

[26] E. D. Sloan Jr., C. A. Koh, Clathrate Hydrates of natural Gases, 3 rd edition, Chemical Industries, CRC Press, Taylor & Francis Group, 2008.

[27] G. K. Anderson, Enthalpy of dissociation and hydration number of methane hydrate from the Clapeyron equation, Journal of Chemical Thermodynamics, Vol. 36, 2004, pp. 1119- 1127.

[28] Emerging issues update in our global environment, United Nations Environment Programme (UNEP) Year Book, 2014.

[29] S. M. Lu, A global survey of gas hydrate development and reserves: Specifically in the marine field, Renewable and Sustainable Energy Reviews, Vol. 41, 2015, pp. 884-900.

[30] S. J. Howe, Production modelling and economic evaluation of a potential gas hydrate pilot production program on the North Slope of Alaska, M.S. Thesis, University of Alaska Fairbanks, 2004.

[31] S. Hancock, T. S. Collett, M. Pooladi-Darvish, S. Gerami, G. Moridis, T. Okazawa, K. Osadetz, S. Dallimore, B. Weatherill, A preliminary investigation on the economics of onshore gas hydrate production based on the Mallik Field discovery, American Association of Petroleum Geologists Hedberg, 2004.

[32] Leadership case study: Oil & gas industry energy technology solutions, IHS Energy, 2014.

[33] M. R. Walsh, C. A. Koh, E. D. Sloan Jr., A. K. Sum, D. T. Wu, Microsecond simulations of spontaneous methane hydrate nucleation and growth, Science, Vol. 326, 2009, pp. 1095- 1098.

[34] G. J. Moridis, T. S. Collett, R. Boswell, M. Kurihara, M. T. Reagan, C. A. Koh, E. D. Sloan Jr., Toward Production from Gas Hydrates: Current status, assessment of resources, and simulation-based evaluation of technology and potential, Society of Petroleum Engineers, Vol. 12, 2008, pp. 1-25.

[35] G. Buchholz, S. Droge, U. R. Fritsche, L. Ganzer, H. Herm-Stapleberg, G. Meiners, J. Muller, H. R. Ruske, H. J. Uth, M. Weyand, Fracking for shale gas production, SRU German Advisory Council on the Environment, 2013.

[36] C. Clark, A. Burnham, C. Harto, R. Horner, Hydraulic Fracturing and Shale Gas Production: Technology, impacts, and regulation, Environmental Science Division, Argonne National Laboratory, 2013.

[37] S. Dallimore, T. S. Collett, Scientific Results from the Mallik 2002 Gas Hydrate Production Research Well Program, MacKenzie Delta, Northwest Territories, Canada, Geological Survey of Canada Bulletin 585, 2005.

[38] K. Takase, Renewable Energy burst in Japan, Special reports, Nautilus Institute for Security and Sustainability, 2014.

[39] Renewable 2015: Global Status Report, Renewable Energy Policy Network for the 21st Century (REN21), 2015.

[40] Renewable Japan Status report 2014, Institute of Sustainable Energy Policies (ISEP), 2014.

[41] B. Decourt, S. Alias, R. Debarre, Gas hydrates: Taking the heat out of the burning-ice debate - Potential and future of Gas Hydrates, SBC Energy Institute, 2015.

[42] L. Lester, Energy relations and policymaking in Asia, A. Kiani, T. Mezher, S. Griffiths, S. El Khatib, Potential impact of methane hydrate development on GCC and NEA energy trade, Springer Singapore, Singapore, 2016.

WSEAS Transactions on Business and Economics, ISSN / E-ISSN: 1109-9526 / 2224-2899, Volume 14, 2017, Art. #12, pp. 110-119


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