Detection and impacts of leakage from sub-seafloor deep geological carbon dioxide storage

Jerry Blackford; Henrik Stahl; Jonathan M. Bull; Benoit J. P. Berges; Melis Cevatoglu; Anna Lichtschlag; Douglas Connelly; Rachael H. James; Jun Kita; Dave Long; Mark Naylor; Kiminori Shitashima; Dave Smith; Peter Taylor; Ian Wright; Maxine Akhurst; Baixin Chen; Tom M. Gernon; Chris Hauton; Masatoshi Hayashi; Hideshi Kaieda; Timothy G. Leighton; Toru Sato; Martin D. J. Sayer; Masahiro Suzumura; Karen Tait; Mark E. Vardy; Paul R. White; Steve Widdicombe

doi:10.1038/NCLIMATE2381

Detection and impacts of leakage from sub-seafloor deep geological carbon dioxide storage

Jerry Blackford
, Henrik Stahl
, Jonathan M. Bull
, Benoit J. P. Berges
, Melis Cevatoglu
, Anna Lichtschlag
, Douglas Connelly
, Rachael H. James
, Jun Kita
, Dave Long
, Mark Naylor
, Kiminori Shitashima
, Dave Smith
, Peter Taylor
, Ian Wright
, Maxine Akhurst
, Baixin Chen
, Tom M. Gernon
, Chris Hauton
, Masatoshi Hayashi

Hideshi Kaieda, Timothy G. Leighton, Toru Sato, Martin D. J. Sayer, Masahiro Suzumura, Karen Tait, Mark E. Vardy, Paul R. White, Steve Widdicombe

SAMS UHI

Publikation: Article › Begutachtung

194 Zitate (Scopus)

172 Downloads (Pure)

Abstract

Fossil fuel power generation and other industrial emissions of carbon dioxide are a threat to global climate1, yet many economies will remain reliant on these technologies for several decades2. Carbon dioxide capture and storage (CCS) in deep geological formations provides an effective option to remove these emissions from the climate system3. In many regions storage reservoirs are located offshore4, 5, over a kilometre or more below societally important shelf seas6. Therefore, concerns about the possibility of leakage7, 8 and potential environmental impacts, along with economics, have contributed to delaying development of operational CCS. Here we investigate the detectability and environmental impact of leakage from a controlled sub-seabed release of CO2. We show that the biological impact and footprint of this small leak analogue (<1 tonne CO2 d−1) is confined to a few tens of metres. Migration of CO2 through the shallow seabed is influenced by near-surface sediment structure, and by dissolution and re-precipitation of calcium carbonate naturally present in sediments. Results reported here advance the understanding of environmental sensitivity to leakage and identify appropriate monitoring strategies for full-scale carbon storage operations.

Originalsprache	English
Seiten (von - bis)	1011-1016
Seitenumfang	5
Fachzeitschrift	Nature Climate Change
Jahrgang	4
Ausgabenummer	11
Frühes Online-Datum	28 Sept. 2014
DOIs	https://doi.org/10.1038/NCLIMATE2381
Publikationsstatus	E-pub ahead of print - 28 Sept. 2014

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10.1038/NCLIMATE2381Lizenz: CC BY-NC

Blackford_et_al_Nature_Climate_Change_QICS_postprintSubmitted manuscript, 614 KBLizenz: CC BY-NC

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Blackford, J., Stahl, H., Bull, J. M., Berges, B. J. P., Cevatoglu, M., Lichtschlag, A., Connelly, D., James, R. H., Kita, J., Long, D., Naylor, M., Shitashima, K., Smith, D., Taylor, P., Wright, I., Akhurst, M., Chen, B., Gernon, T. M., Hauton, C., ... Widdicombe, S. (2014). Detection and impacts of leakage from sub-seafloor deep geological carbon dioxide storage. Nature Climate Change, 4(11), 1011-1016. Vorzeitige Online-Publikation. https://doi.org/10.1038/NCLIMATE2381

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title = "Detection and impacts of leakage from sub-seafloor deep geological carbon dioxide storage",

abstract = "Fossil fuel power generation and other industrial emissions of carbon dioxide are a threat to global climate1, yet many economies will remain reliant on these technologies for several decades2. Carbon dioxide capture and storage (CCS) in deep geological formations provides an effective option to remove these emissions from the climate system3. In many regions storage reservoirs are located offshore4, 5, over a kilometre or more below societally important shelf seas6. Therefore, concerns about the possibility of leakage7, 8 and potential environmental impacts, along with economics, have contributed to delaying development of operational CCS. Here we investigate the detectability and environmental impact of leakage from a controlled sub-seabed release of CO2. We show that the biological impact and footprint of this small leak analogue (<1 tonne CO2 d−1) is confined to a few tens of metres. Migration of CO2 through the shallow seabed is influenced by near-surface sediment structure, and by dissolution and re-precipitation of calcium carbonate naturally present in sediments. Results reported here advance the understanding of environmental sensitivity to leakage and identify appropriate monitoring strategies for full-scale carbon storage operations.",

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Blackford, J, Stahl, H, Bull, JM, Berges, BJP, Cevatoglu, M, Lichtschlag, A, Connelly, D, James, RH, Kita, J, Long, D, Naylor, M, Shitashima, K, Smith, D, Taylor, P, Wright, I, Akhurst, M, Chen, B, Gernon, TM, Hauton, C, Hayashi, M, Kaieda, H, Leighton, TG, Sato, T, Sayer, MDJ, Suzumura, M, Tait, K, Vardy, ME, White, PR & Widdicombe, S 2014, 'Detection and impacts of leakage from sub-seafloor deep geological carbon dioxide storage', Nature Climate Change, Jg. 4, Nr. 11, S. 1011-1016. https://doi.org/10.1038/NCLIMATE2381

TY - JOUR

T1 - Detection and impacts of leakage from sub-seafloor deep geological carbon dioxide storage

AU - Blackford, Jerry

AU - Stahl, Henrik

AU - Bull, Jonathan M.

AU - Berges, Benoit J. P.

AU - Cevatoglu, Melis

AU - Lichtschlag, Anna

AU - Connelly, Douglas

AU - James, Rachael H.

AU - Kita, Jun

AU - Long, Dave

AU - Naylor, Mark

AU - Shitashima, Kiminori

AU - Smith, Dave

AU - Taylor, Peter

AU - Wright, Ian

AU - Akhurst, Maxine

AU - Chen, Baixin

AU - Gernon, Tom M.

AU - Hauton, Chris

AU - Hayashi, Masatoshi

AU - Kaieda, Hideshi

AU - Leighton, Timothy G.

AU - Sato, Toru

AU - Sayer, Martin D. J.

AU - Suzumura, Masahiro

AU - Tait, Karen

AU - Vardy, Mark E.

AU - White, Paul R.

AU - Widdicombe, Steve

PY - 2014/9/28

Y1 - 2014/9/28

N2 - Fossil fuel power generation and other industrial emissions of carbon dioxide are a threat to global climate1, yet many economies will remain reliant on these technologies for several decades2. Carbon dioxide capture and storage (CCS) in deep geological formations provides an effective option to remove these emissions from the climate system3. In many regions storage reservoirs are located offshore4, 5, over a kilometre or more below societally important shelf seas6. Therefore, concerns about the possibility of leakage7, 8 and potential environmental impacts, along with economics, have contributed to delaying development of operational CCS. Here we investigate the detectability and environmental impact of leakage from a controlled sub-seabed release of CO2. We show that the biological impact and footprint of this small leak analogue (<1 tonne CO2 d−1) is confined to a few tens of metres. Migration of CO2 through the shallow seabed is influenced by near-surface sediment structure, and by dissolution and re-precipitation of calcium carbonate naturally present in sediments. Results reported here advance the understanding of environmental sensitivity to leakage and identify appropriate monitoring strategies for full-scale carbon storage operations.

AB - Fossil fuel power generation and other industrial emissions of carbon dioxide are a threat to global climate1, yet many economies will remain reliant on these technologies for several decades2. Carbon dioxide capture and storage (CCS) in deep geological formations provides an effective option to remove these emissions from the climate system3. In many regions storage reservoirs are located offshore4, 5, over a kilometre or more below societally important shelf seas6. Therefore, concerns about the possibility of leakage7, 8 and potential environmental impacts, along with economics, have contributed to delaying development of operational CCS. Here we investigate the detectability and environmental impact of leakage from a controlled sub-seabed release of CO2. We show that the biological impact and footprint of this small leak analogue (<1 tonne CO2 d−1) is confined to a few tens of metres. Migration of CO2 through the shallow seabed is influenced by near-surface sediment structure, and by dissolution and re-precipitation of calcium carbonate naturally present in sediments. Results reported here advance the understanding of environmental sensitivity to leakage and identify appropriate monitoring strategies for full-scale carbon storage operations.

KW - 7ref2021

U2 - 10.1038/NCLIMATE2381

DO - 10.1038/NCLIMATE2381

M3 - Article

SN - 1758-678X

VL - 4

SP - 1011

EP - 1016

JO - Nature Climate Change

JF - Nature Climate Change

IS - 11

ER -

Detection and impacts of leakage from sub-seafloor deep geological carbon dioxide storage

Abstract

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