Carbon capture and storage at the end of a lost decade

Following the landmark 2015 United Nations Paris Agreement, a growing number of countries are committing to the transition to net-zero emissions. Carbon capture and storage (CCS) has been consistently heralded to directly address emissions from the energy and industrial sectors and forms a significa...

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Published inOne earth (Cambridge, Mass.) Vol. 4; no. 11; pp. 1569 - 1584
Main Authors Martin-Roberts, Emma, Scott, Vivian, Flude, Stephanie, Johnson, Gareth, Haszeldine, R. Stuart, Gilfillan, Stuart
Format Journal Article
LanguageEnglish
Published Elsevier Inc 19.11.2021
Subjects
capacity
carbon capture
carbon dioxide
carbon sequestration
energy
EOR
fossil fuels
issues and policy
net-zero
research and development
resources
storage
United Nations Framework Convention on Climate Change
fossil fuels
net-zero
carbon capture
resources
EOR
storage
capacity
Online AccessGet full text
ISSN2590-3322
2590-3322
DOI10.1016/j.oneear.2021.10.002

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Abstract Following the landmark 2015 United Nations Paris Agreement, a growing number of countries are committing to the transition to net-zero emissions. Carbon capture and storage (CCS) has been consistently heralded to directly address emissions from the energy and industrial sectors and forms a significant component of plans to reach net-zero. However, despite the critical importance of the technology and substantial research and development to date, CCS deployment has been slow. This review examines deployment efforts over the last decade. We reveal that facility deployment must increase dramatically from current levels, and much work remains to maximize storage of CO2 in vast subsurface reserves. Using current rates of deployment, CO2 storage capacity by 2050 is projected to be around 700 million tons per year, just 10% of what is required. Meeting the net-zero targets via CCS ambitions seems unlikely unless worldwide coordinated efforts and rapid changes in policy take place. [Display omitted] Carbon capture and storage (CCS) provides a direct means to achieve the transition to net-zero. We show that the gap between what is expected from CCS and what has been delivered is still significant. Facility deployment, proven storage capacity, and storage rates must increase to play a part in CO2 mitigation. There must also be a greater global effort with government and multinational corporation engagement, and a rapid step-change in policy to avoid disillusionment toward the usefulness of CCS.
AbstractList Following the landmark 2015 United Nations Paris Agreement, a growing number of countries are committing to the transition to net-zero emissions. Carbon capture and storage (CCS) has been consistently heralded to directly address emissions from the energy and industrial sectors and forms a significant component of plans to reach net-zero. However, despite the critical importance of the technology and substantial research and development to date, CCS deployment has been slow. This review examines deployment efforts over the last decade. We reveal that facility deployment must increase dramatically from current levels, and much work remains to maximize storage of CO2 in vast subsurface reserves. Using current rates of deployment, CO2 storage capacity by 2050 is projected to be around 700 million tons per year, just 10% of what is required. Meeting the net-zero targets via CCS ambitions seems unlikely unless worldwide coordinated efforts and rapid changes in policy take place. [Display omitted] Carbon capture and storage (CCS) provides a direct means to achieve the transition to net-zero. We show that the gap between what is expected from CCS and what has been delivered is still significant. Facility deployment, proven storage capacity, and storage rates must increase to play a part in CO2 mitigation. There must also be a greater global effort with government and multinational corporation engagement, and a rapid step-change in policy to avoid disillusionment toward the usefulness of CCS.
Following the landmark 2015 United Nations Paris Agreement, a growing number of countries are committing to the transition to net-zero emissions. Carbon capture and storage (CCS) has been consistently heralded to directly address emissions from the energy and industrial sectors and forms a significant component of plans to reach net-zero. However, despite the critical importance of the technology and substantial research and development to date, CCS deployment has been slow. This review examines deployment efforts over the last decade. We reveal that facility deployment must increase dramatically from current levels, and much work remains to maximize storage of CO₂ in vast subsurface reserves. Using current rates of deployment, CO₂ storage capacity by 2050 is projected to be around 700 million tons per year, just 10% of what is required. Meeting the net-zero targets via CCS ambitions seems unlikely unless worldwide coordinated efforts and rapid changes in policy take place.
Author Gilfillan, Stuart
Haszeldine, R. Stuart
Scott, Vivian
Johnson, Gareth
Flude, Stephanie
Martin-Roberts, Emma
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  orcidid: 0000-0002-6718-601X
  surname: Martin-Roberts
  fullname: Martin-Roberts, Emma
  email: emma.martin-roberts@ed.ac.uk
  organization: School of GeoSciences, University of Edinburgh, Grant Institute, the Kings Buildings, James Hutton Road, EH9 3FE Edinburgh, UK
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  givenname: Vivian
  surname: Scott
  fullname: Scott, Vivian
  organization: School of GeoSciences, University of Edinburgh, Grant Institute, the Kings Buildings, James Hutton Road, EH9 3FE Edinburgh, UK
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  surname: Flude
  fullname: Flude, Stephanie
  organization: Department of Earth Sciences, University of Oxford, South Parks Road, OX1 3AN Oxford, UK
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  givenname: Gareth
  orcidid: 0000-0002-3151-5045
  surname: Johnson
  fullname: Johnson, Gareth
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  surname: Haszeldine
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  organization: School of GeoSciences, University of Edinburgh, Grant Institute, the Kings Buildings, James Hutton Road, EH9 3FE Edinburgh, UK
– sequence: 6
  givenname: Stuart
  orcidid: 0000-0003-1929-2843
  surname: Gilfillan
  fullname: Gilfillan, Stuart
  organization: School of GeoSciences, University of Edinburgh, Grant Institute, the Kings Buildings, James Hutton Road, EH9 3FE Edinburgh, UK
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net-zero
carbon capture
resources
EOR
storage
capacity
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Snippet Following the landmark 2015 United Nations Paris Agreement, a growing number of countries are committing to the transition to net-zero emissions. Carbon...
Following the landmark 2015 United Nations Paris Agreement, a growing number of countries are committing to the transition to net-zero emissions. Carbon...
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SubjectTerms capacity
carbon capture
carbon dioxide
carbon sequestration
energy
EOR
fossil fuels
issues and policy
net-zero
research and development
resources
storage
United Nations Framework Convention on Climate Change
Title Carbon capture and storage at the end of a lost decade
URI https://dx.doi.org/10.1016/j.oneear.2021.10.002
https://www.proquest.com/docview/2636574363
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