Sustainable Design of Multiscale CO2 Electrochemical Conversion

Mar Perez-Fortes*, Josephine Vos, Thijmen Wiltink, Hans de Bruijn, Tarkan Tan, Nevin Mutlu, Floor Alkemade, Andrea Ramirez Ramirez

*Corresponding author for this work

Research output: Chapter in Book/Conference proceedings/Edited volumeConference contributionScientific

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Abstract

The storage of renewable electricity in chemical bonds is a compelling technological option that combines flexibility with the synthesis of high energy-dense fuels and chemicals and may use CO2 as raw material. The electrochemical conversion of CO2 is not yet a mature technology. Both fields, electrochemical conversion and carbon dioxide utilisation (CDU), have their own trade-offs; CO2 electrochemical reduction (CO2ER) environmental and economic performance is highly context-dependent. The successful deployment of CO2 electrochemical conversion will depend not only on the further development and scaling of the technology but also on finding appropriate combinations of technologies, business models, and socioeconomic strategies. The current project aims to create critical knowledge on the sustainable implementation of CO2 electrochemical devices for a variety of contexts. The research approach presented in the current work will develop a multidisciplinary framework to assess the contributions and trade-offs of CO2 electrochemical systems, including centralised and decentralised configurations, which are evaluated under realistic conditions. This is a crucial step in understanding the role and contribution of CO2ER within the different CO2 mitigation options in place in the upcoming years. To achieve the project’s goal, we propose a multidisciplinary methodology that includes process systems engineering (PSE) and operations research (OR) tools, and humanistic and social sciences methodologies. Modelling and optimisation techniques, value-sensitive design, and identification of government and market-based governance interventions will help identifying potential areas of improvement and bottlenecks to successfully bring CO2ER to the market. The assessment will be performed at several levels: unit (reaction pathways), process (scheduling and operation, plant layout optimisation), supply chain (optimisation under deterministic and stochastic conditions), and system (social, governance and markets perspectives) of CO2ER. The project results will (i) propose optimal CO2ER-based plants and (ii) supply chains under different contexts; (iii) translate stakeholders’ sustainability value into design requirements for CO2ER; (iv) propose a list of government interventions and market mechanisms that will allow CO2ER market penetration, and (v) identify, quantify and mitigate the influence of the most relevant sources of uncertainty.
Original languageEnglish
Title of host publicationProceedings of 16th Greenhouse Gas Control Technologies Conference 2022 (GHGT-16)
Pages1-9
DOIs
Publication statusPublished - 2022
EventGreenhouse Gas Control Technologies Conference - Calgary, Canada
Duration: 23 Oct 202224 Oct 2022
Conference number: 16
https://papers.ssrn.com/sol3/JELJOUR_Results.cfm?form_name=journalbrowse&journal_id=4219537

Conference

ConferenceGreenhouse Gas Control Technologies Conference
Abbreviated titleGHGT-16
Country/TerritoryCanada
CityCalgary
Period23/10/2224/10/22
Internet address

Keywords

  • CO2 electrochemical reduction
  • CO2 utilisation
  • multiscale modelling
  • sustainable design

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