Free Standard AU & NZ Shipping For All Book Orders Over $80!
Register      Login
Australian Energy Producers Journal Australian Energy Producers Journal Society
Journal of Australian Energy Producers
Shopping Cart: ( empty )
You are here: Home > Journals > EP > EP23150
RESEARCH ARTICLE (Non peer reviewed)
Contents Vol 64 (S1: Proceedings)

Emissions reduction in LNG production facilities through emerging post-combustion carbon capture and storage technologies

David T. Kearns A B *
+ Author Affiliations
- Author Affiliations

A Global CCS Institute, Melbourne, Vic., Australia.

B Environmental Risk Management, Melbourne, Vic., Australia.




David T. Kearns is a Senior Technical Advisor at the Global CCS Institute, based in Melbourne. He has 25 years of experience in engineering design, plant operations, consulting, research, and think tanks. His experience spans a range of sectors, including oil and gas, petrochemicals, cement, biofuels, pulp and paper, and hydrogen. David is an Honorary Fellow of the Department of Chemical Engineering at the University of Melbourne, and a Fellow of the Australian Institute of Energy. David holds BE (Hons) and PhD degrees in Chemical Engineering and a BCom in Management, all from Monash University.
* Correspondence to: david.kearns@globalccsinstitute.com

Australian Energy Producers Journal 64 S160-S165 https://doi.org/10.1071/EP23150
Accepted: 1 March 2024  Published: 16 May 2024

© 2024 The Author(s) (or their employer(s)). Published by CSIRO Publishing on behalf of Australian Energy Producers.

Abstract

The liquefied natural gas (LNG) sector relies extensively on gas turbines for on-site power generation and to drive refrigeration compressors. They provide an efficient and reliable energy source for LNG operations in remote locations. With upcoming changes to the Safeguard Mechanism in Australia, there is an increased focus on Scope 1 emissions, so management and targeted reduction are a priority to reduce liabilities. Despite technology advancements, gas turbines remain one of the largest sources of carbon dioxide (CO2) emissions in LNG production facilities. Also, in Australia, many facilities are not grid-connected, meaning that displacement of Scope 1 emissions through renewable electricity sourcing is a challenge. To develop deeper cuts in Scope 1 emissions, one solution is to deploy post-combustion carbon capture and storage (CCS) on existing gas turbines, with the potential to reduce associated emissions by over 90%. Globally, a number of LNG facilities are already deploying CCS to permanently store reservoir CO2 from the LNG processing trains. Several Australian LNG facilities are located in close proximity to potential CO2 storage reservoirs, meaning that a coordinated approach to both reservoir and post-combustion CO2 should be considered when sizing pipelines, shipping systems and storage wells to optimise and leverage the required investment. This paper outlines the technological, economic and policy aspects of integrating both reservoir post-combustion CCS on LNG facilities, including barriers and opportunities for deployment. It will discuss new developments and enablers for CCS to be more widely deployed at LNG production sites.

Keywords: Australia, carbon capture and storage, CO2 capture, decarbonisation, emissions reduction, gas turbines, liquefied natural gas, sustainability.

Biographies

EP23150_B1.gif

David T. Kearns is a Senior Technical Advisor at the Global CCS Institute, based in Melbourne. He has 25 years of experience in engineering design, plant operations, consulting, research, and think tanks. His experience spans a range of sectors, including oil and gas, petrochemicals, cement, biofuels, pulp and paper, and hydrogen. David is an Honorary Fellow of the Department of Chemical Engineering at the University of Melbourne, and a Fellow of the Australian Institute of Energy. David holds BE (Hons) and PhD degrees in Chemical Engineering and a BCom in Management, all from Monash University.

References

Aker Carbon Capture (2024) Just Catch. Available at https://akercarboncapture.com/offerings/just-catch/ [accessed 8 February 2024]

Australia Pacific LNG (2010) Volume 5: Attachments Attachment 31: Greenhouse Gas Assessment-LNG Facility - Project EIS. Available at https://aplng.com.au/wp-content/uploads/2021/07/Vol_5_Att_31_GreenhouseGasAssessment.pdf [accessed 8 February 2024]

Carbon Clean (2021) Introducing CycloneCC: Effective, efficient carbon capture technology. Available at https://www.carbonclean.com/blog/efficient-carbon-capture [accessed 8 February 2024]

Chevron Australia (2022) Wheatstone LNG Plant Greenhouse Gas Management Plan. Available at https://australia.chevron.com/-/media/australia/our-businesses/documents/wheatstone-ghg-management-plan.pdf [accessed 8 February 2024]

Heath C, Ong C (2022) Greenhouse gas emissions from the liquified natural gas industry in Australia. CSIRO, Australia. Available at https://agit.org.au/wp-content/uploads/2023/05/Greenhouse-gas-emissions-from-LNG-CSIRO-final.pdf

IEAGHG (2019) Towards Zero Emissions CCS in Power Plants Using Higher Capture Rates or Biomass. IEAGHG Technical Report 2019-02. Available at https://documents.ieaghg.org/index.php/s/CLIZIvBI6OdMFnf

INPEX (2010) Ichthys Gas Field Development Project. Draft Environmental Impact Statement - Ch.9 Greenhouse Gas Management. Available at https://www.inpex.com.au/media/v2vnjpba/draft-environmental-impact-statement-11-chapter-9-greenhouse-gas-management.pdf [accessed 8 February 2024]

Kearns D, Liu H, Consoli C (2021) Technology readiness and costs of CCS. Available at https://www.globalccsinstitute.com/wp-content/uploads/2022/03/CCE-CCS-Technology-Readiness-and-Costs-22-1.pdf [accessed 8 February 2024]