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      KCI등재

      다채널 지표토양 CO2 농도 모니터링(SCM) 시스템 개발 및적용성 평가 연구 = Applicability of the Multi-Channel Surface-soil CO2-concentration Monitoring (SCM) System as a Surface Soil CO2 Monitoring Tool

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      https://www.riss.kr/link?id=A104624423

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      다국어 초록 (Multilingual Abstract)

      Monitoring of CO2 release through the ground surface is essential to confirm the safety of carbon storage projects. Weconducted a feasibility study of the multi-channel surface-soil CO2-concentration monitoring (SCM) system as a soil CO2monitoring too...

      Monitoring of CO2 release through the ground surface is essential to confirm the safety of carbon storage projects. Weconducted a feasibility study of the multi-channel surface-soil CO2-concentration monitoring (SCM) system as a soil CO2monitoring tool with a small scale injection test. The background concentrations showed the distinct diurnal variation. Thenegative relation of CO2 with temperature and the low CO2 concentrations during the day imply that surface-soil CO2depends on photosynthesis and respiration. After 4.2 kg of CO2 injection (1 m depth for 29 minutes), surface-soil CO2concentrations increased in the all five chambers, which were located less than 2.8 m of distance from each other. The CO2concentrations seem to be recovered to the background around 4 hours after the injection ended. To determine the leakage,the data from Chamber 2 and 5 with low increase rates were used for statistical analyses. Coefficient of variation for 30minutes (CV30min.) is efficient to determine a leakage signal, with reflecting the fast change in CO2 concentrations.
      Consequently, SCM and CV30min could be applied for an efficient monitoring tool to detect CO2 release through theground surface. Also, this study provides ideas for establishing action steps after leakage detection.

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      참고문헌 (Reference)

      1 Zhang, Y., "Vadose zone remediation of carbon dioxide leakage from geologic carbon dioxide sequestration" 3 : 858-866, 2004

      2 Jenkins, C., "Statistical aspect of monitoring and verification" 13 : 215-229, 2013

      3 Schacht, U., "Soil gas monitoring of the Otway project demonstration site in SE victoria, Austria" 24 : 14-29, 2014

      4 Scanlon, B.R., "Soil Physics Companion" CRC Press 297-341, 2001

      5 Krevor, S., "Rapid detection and characterization of surface CO2 leakage through the real-time, measurement of δ13C signature in CO2 flux from the ground" 4 : 811-815, 2010

      6 Romanak, K.D., "Process-based approach to CO2 leakage detection by vadose zone gas monitoring at geologic CO2 storage sites" 39 : L15405-, 2012

      7 Bernardo, C., "Permanent shallow subsoil CO2 flux chamber for monitoring of onshore CO2 geological storage sites" 5 : 565-570, 2011

      8 Beaubien, S.E., "Monitoring of near-surface gas geochemistry at the Weyburn Canda, CO2-EOR site, 2001-2011" 16 : 236-262, 2013

      9 Garcia-Anton, E., "Main drivers of diffusive and advective processes of CO2-gas exchange between a shallow vadose zone and the atmosphere" 21 : 113-129, 2014

      10 IPCC, "IPCC Special Report on Carbon Dioxide Capture and Storage" Cambridge Univ. Pub 431-, 2005

      1 Zhang, Y., "Vadose zone remediation of carbon dioxide leakage from geologic carbon dioxide sequestration" 3 : 858-866, 2004

      2 Jenkins, C., "Statistical aspect of monitoring and verification" 13 : 215-229, 2013

      3 Schacht, U., "Soil gas monitoring of the Otway project demonstration site in SE victoria, Austria" 24 : 14-29, 2014

      4 Scanlon, B.R., "Soil Physics Companion" CRC Press 297-341, 2001

      5 Krevor, S., "Rapid detection and characterization of surface CO2 leakage through the real-time, measurement of δ13C signature in CO2 flux from the ground" 4 : 811-815, 2010

      6 Romanak, K.D., "Process-based approach to CO2 leakage detection by vadose zone gas monitoring at geologic CO2 storage sites" 39 : L15405-, 2012

      7 Bernardo, C., "Permanent shallow subsoil CO2 flux chamber for monitoring of onshore CO2 geological storage sites" 5 : 565-570, 2011

      8 Beaubien, S.E., "Monitoring of near-surface gas geochemistry at the Weyburn Canda, CO2-EOR site, 2001-2011" 16 : 236-262, 2013

      9 Garcia-Anton, E., "Main drivers of diffusive and advective processes of CO2-gas exchange between a shallow vadose zone and the atmosphere" 21 : 113-129, 2014

      10 IPCC, "IPCC Special Report on Carbon Dioxide Capture and Storage" Cambridge Univ. Pub 431-, 2005

      11 Annunziatellis, A., "Gas migration along fault systems and through the vadose zone in the Latera caldera (central Italy): implications for CO2 geological storage" 2 : 353-372, 2008

      12 Jung, N.H., "Fault-controlled CO2 leakage from natural reservation in the Colorado Plateau, East-Central Utah" 403 : 358-367, 2014

      13 Lewicki, J.L., "Dynamics of CO2 fluxes and concentrations during a shallow subsurface CO2 release" 60 : 285-297, 2010

      14 KIGAM, "Development of CO2 Behavior Monitoring Technologies in Deep Geological Media" 125-, 2013

      15 Cook, P.J., "Clean Energy, Climate and Carbon" CIR Pub 273-, 2014

      16 NETL, "Best practices for monitoring, varification, and accounting of CO2 stored in deep geologic formation-2012 update" 136-, 2012

      17 Johnson, J.W., "Best Practices for Validating CO2 Geological Storage: Observations and Guidance from the IEAGHG Weyburn-Midale CO2 Monitoring and Storage Project" Geoscience Pub 119-154, 2012

      18 Schlömer, S., "Baseline soil gas measurements as part of a monitoring concept above a projected CO2 injection formation - A case study from Northern Germany" 20 : 57-72, 2014

      19 Feitz, A., "An assessment of near surface CO2 leakage detection techniques under Australian condition" 63 : 3891-3906, 2014

      20 Schloemer, S., "A review of continuous soil gas monitoring related to CCS - Technical advances and lessons learned" 30 : 148-160, 2013

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      2020-01-01 평가 등재학술지 유지 (재인증) KCI등재
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      2016 0.3 0.3 0.35
      KCIF(4년) KCIF(5년) 중심성지수(3년) 즉시성지수
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