박사
확률통계기법 기반의 국내 탄산지하수 특성 연구 = The characteristics of CO2-rich domestic groundwater using probability density function
김광구
2015년
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확률통계기법 기반의 국내 탄산지하수 특성 연구 = The characteristics of CO2-rich domestic groundwater using probability density function' 의 주제별 논문영향력
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| 동일주제 총논문수 | 논문피인용 총횟수 | 주제별 논문영향력의 평균 |
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주제별 논문영향력
' 확률통계기법 기반의 국내 탄산지하수 특성 연구 = The characteristics of CO2-rich domestic groundwater using probability density function' 의 참고문헌
-
한국자원연구소, , ‘안동 지질도폭 설명서(1:250,000)’KR-96(S)-1, p.67 [1996]
-
한국자원연구소, , ‘부산 지질도폭 설명서(1:250,000)’KR-98(S)-1, p.62 [1998]
-
천안도폭 지질보고서(1:50,000)
-
천안도폭 지질보고서(1:50,000)
-
천안도폭 지질보고서(1:50,000)
-
중소기업청 , ,‘ 순위데이터의 분석(PPT)’대한상공회의소 싱글PPM 품 질혁신추진본부 [2011]
-
이산화탄소 육상지중 저장을 위한 탐사?평가시 환경안정성 평 가 기반조성에 관한 연구
-
온실가스 감축을 위한 이산화탄소 지중저장 기술의 현황 및 전망
-
부산지역 해안용출수의 수리지질학적 특성연구
-
부산 동부해안 지하수의 물리적 및 화학적 특성
-
부산 동남해안 지역의 수리동역학적 해수침투 특성연구
-
부산 금정지역 지하수의 수리지구화학적 특성 연구
-
농어촌진흥공사 , , ‘경북 문경지구 온천자원조사 보고서’, pp.539 동아대학교 생물통계학과, 2012‘두 집단의 비교(t-분석)’ [1995]
-
국립지질광물연구소, , ‘한국지질도 현리 도폭 (1:50000) 및 도폭설명 서’ [1975]
-
국립지질광물연구소‘한국지질도 장전도폭’ (1:250,000) [1973]
-
국립광업연구소‘광산조사연구보고’, Vol. 1, pp. 117-149 [1968]
-
‘한국의 지질과 광물자원’
-
‘이산화탄소 포집 및 지중저장기술(CCS) 특허동향보고서’
-
‘이산화탄소 저장 기술의 현황 및 전망’
-
‘부산지역의 수리지질층서에 따른 지하수오염 특성(II)’
-
‘미국의 지하수 오염취약성 평가개념’
-
‘문경탄전 오정산일대의 지질구조’
-
‘동래?월내도폭(1:50000) 및 설명서’
-
‘도시지역의 토지용도별 지하수 오염특성 연구-부산광역시를 중심으로’
-
‘금강지류 소유역 일대의 질소성분의 물리?화학적 특성’
-
‘경북 영천지역 지 하수의 지구화학 및 환경동위원소 연구’Bae, Dae-Seok Choi, Byoung-Young Jung, Do-Hwan Kim, Geon-Young Koh, Yong-Kwon Won, Chong-Ho 고용권 김건영 배대석 원종호 정도환 최병영 한국지하수토양환경학회지 제12권제4호, pp. 35-53 [2007]
-
‘강원도지역 탄산형 지하수의 진화경로에 관한 지화학모델링 모델링‘
-
‘11장. 두 개의 표본평균 혹은 표본비율을 이용한 가설검 정’, 경북대학교 경영학부
-
http://rinte.net/234,‘지하수의 수질 및 환경지질학에 대해 알아보자’Rinte IT Commentary
-
Zaiontz Charles, 2014, ‘Real Statistics Using Excel’, www.real-statistics.com
-
Waltham David , 1994, ‘Mathematics: a simple tool for geologists’, CHAPMAN & HALL, pp. 107-129
-
So, C. S., Shelton, K. L., Seidemann, D. E. and Skinner, B. J., 1983, ‘The Dae Hwatungsten-molybdenum mine, Republic of Korea’, Econ, Geol., v.78, pp. 920-930
-
Oracle, 2011, ‘ Predictive Analytics: Bringing The Tools To The Data’, An Oracle White Paper
-
Nordstrom Darrell Kirk, Ball James W., Donahoe Rona J., Whittemore Donald, 1989,‘Groundwater chemistry and water-rock interactions at Stripa’, Geochim. Cosmochim. Acta, Vol. 53, pp. 1727-1740
-
National Energy Technology Laboratory, 2012, ‘BEST PRACTICES for Monitoring, Verification, and Accounting of CO₂ Stored in Deep Geologic Formations-2012 update’, DOE/NETL-2012/1568
-
National Energy Technology Laboratory, 2011, ‘Risk Analysis and Simulation for Geologic Storage of CO ’, ₂ DOE/NETL-2011/1459
-
National Energy Technology Laboratory, 2010, ‘Site Screening, Selection, and Initial Characterization for Storage of CO₂ in Deep Geologic Formations’, DOE/NETL-401/090808, pp. 33-53
-
Montgomery John H., 2000, ‘Groundwater chemicals: desk reference’, 3rd edition., CRC Lewis Publishers, p. 1345
-
Mirecki June E., 2006, ‘Geochemical Models of Water-Quality Changes During Aquifer Stroage Recovery(ASR) Cycle Tests, Phase I: Geochemical Models Using Existing Data, US Army Corps of Engineer
-
McCoy Sean, 2014, ‘CSA Z741-12 and requirments for geologic storage’, CSA (6th international IEA CCS regulatory Network Meeting)
-
Langmuir Donald, 1997, ‘Aquesous Environmental Geochemistry’, PRENTICE HALL, pp. 193-229
-
Koh Yong-Kwon, Choi Byoung-Young, Yun Seong-Taek, Choi Hyeon-Su, Bernhard Mayer, Ryoo Si-Won, 2008, ‘Origin and evolution of two contrasting thermal groundwaters (CO₂-rich and alkaline) in the Jungwon area, South Korea: Hydrochemical and isotopic evidence’, Journal of Volcanology and Geothermal Research, pp. 777-786
-
Kim K.. JEONG D.H., KIM Y., KOH Y.-K. , KIM S.-H. AND PARK E., 2008, ‘The geochemical evolution of very dilute CO₂-rich water in Chungcheng Province, Korea: process and pathways’, Geofluids, vol. 8, pp. 3-15
-
Keller E.A., 2000, ‘Environmental geology’, 8th edition. Prentice Hall, Upper Saddle River, New Jersey, p. 562
-
K-COSEM 연구단(윤성택), , ‘CO₂ 저장환경관리기술개발 사업‘환 경기술개발사업 연구개발계획서 [2014]
-
Jeoung Chan Ho , 2005, ‘Hydrochemistry and genesis of CO₂-rich springs from Mesozoic granitoids and their adjacent rocks in South Korea’, Geochemical Journal, Vol.39, pp. 517-530
-
Humez Paouline, Lions Julie, Negrel Philippe, Lagneau Vincent, 2014, ‘CO₂ intrusion in freshwater aquifers: Reiview of geochemical tracers and monitoring tools, classical uses and innovative approaches’, Applied Geochemistry,
-
Hem, J.D., 1985, ‘Study and interpretation of the chemical characteristics of natural water’, U.S. Geological Survey water-supply paper 2254, p. 263
-
GNS, 2009, Opportunities for underground geological storage of CO₂ in New Zealand, Reports CCS-08/01-Risk Assessment Methodologies.
-
European Communities, 2011, ‘Implementation of Directive 2009/31/EC on the Geological Storage of Carbon Dioxide’, Guidance Document 2
-
Eby, G.N., 2004, ‘Principles of environmental chemistry’, Brooks/Cole-Thomson Learning, Pacific Grove, CA, p. 514
-
Davis John C., 2002, ‘Statistics and Data Analysis in Geology’3rd Edition, John Wiley & Sons, pp. 11-112
-
DNV, 2012, ‘Geological Storage of Carbon Dioxide’, RECOMMENDED PRACTICE, DNV-RP-J203
-
Choi Hyeon-Su. Yun Seong-Taek, Koh Yong-Kwon, Mayer Bernhard, Park Seong-Sook, Hutcheon Ian, 2009, ‘Geochemical behavior of rare earth elements during the evolution of CO₂-rich groundwater: A study from the Kangwon district, South Korea’, Chemical Geology, vol. 262, pp. 318-327
-
Choi Hyeon-Su, Koh Young-Kwon, Bae Dae-Seok, Park Seong-Sook, Hutcheon Ian, Yun Seong-Taek, 2005, ‘Estimation of deep-reservoir temperature of CO₂-rich springs in Kangwon district, South Korea’, Journal of volcanology and geothermal research, vol. 141, pp. 77-89
-
Choi Byoung-Young, Yun Seong-Taek, Kim Kyoung-Ho, Choi Hyeon-Su, Chae Gi-Tak , Lee Pyeong-Koo, 2014, ‘Geochemical modeling of CO -water-rock interactions for two different hydrochemical ₂ types of CO₂-rich springs in Kangwon District, Korea’, Journal of Geochemical Exploration
-
Charbeneau Randall J., 2000, ‘Groundwater Hydraulics and Pollutant Transport’, PRENTICE HALL, pp. 179-244
-
Chae Gi-Tak, Jo Min-Ki, Kim Jeong-Chan, Yum Byoung-Woo, 2013, ‘Geochemical Study on CO₂-rich water of Daepyeong area, Korea: Monitoring Implication for CO₂ Geological storage’, Energy Procedia, ELSEVIER, pp. 4366-4373
-
Bert Metz, O Davidson, H De Coninck, M Loos, L Meyer, 2005, ‘carbon dioxide capture and storage’, WMO & UNEP, Cambridge university press, pp. 195-337
-
Bachul Stefan, 2014, ‘Report of the Task Force on Review of CO₂ Storage Efficiency in Deep Saline Aquifers’, Carbon Sequestration Leadership Forum (Technical Groupmeeting in Seoul)
-
Apps John A., Birkholzer Jens T., Spycher Nicolas, Zheng Liange, 2009,‘Groundwater Chemistry Changes as a Result of CO₂ Injection at the ZERT Field Site in Bozeman, Montana, Project Report’, US Geological Survey
-
Appelo, C.A.J. and Postma, D., 1999, ‘Geochemistry, groundwater and pollution’, A.A. Balkema, Rotterdam, pp. 535
-
Ackiewicz Mark, 2014, ‘Proposal for new task force on technical barriers and R&D opportunities for offshore, sub-seabed geologic storage of carbon dioxide’, Carbon Sequestration Leadership Forum (Technical Groupmeeting in Seoul)