Carbon footprint of Power-to-X derived dimethyl ether using the sorption enhanced DME synthesis process

Peter Styring; Peter W. Sanderson; Isaac Gell; Galina Skorikova; Carlos Sánchez-Martínez; Guillermo Garcia-Garcia; Soraya Nicole Sluijter

doi:10.3389/frsus.2022.1057190

Frontiers in Sustainability (Nov 2022)

Carbon footprint of Power-to-X derived dimethyl ether using the sorption enhanced DME synthesis process

Peter Styring,
Peter W. Sanderson,
Isaac Gell,
Galina Skorikova,
Carlos Sánchez-Martínez,
Guillermo Garcia-Garcia,
Soraya Nicole Sluijter

Affiliations

Peter Styring: Department of Chemical and Biological Engineering, UK Centre for Carbon Dioxide Utilisation, The University of Sheffield, Sheffield, United Kingdom
Peter W. Sanderson: Department of Chemical and Biological Engineering, UK Centre for Carbon Dioxide Utilisation, The University of Sheffield, Sheffield, United Kingdom
Isaac Gell: Department of Chemical and Biological Engineering, UK Centre for Carbon Dioxide Utilisation, The University of Sheffield, Sheffield, United Kingdom
Galina Skorikova: Sustainable Technologies for Industrial Processes, Energy Transition, TNO, Petten, Netherlands
Carlos Sánchez-Martínez: Sustainable Process and Energy Systems, Energy Transition, TNO, Delft, Netherlands
Guillermo Garcia-Garcia: Department of Chemical and Biological Engineering, UK Centre for Carbon Dioxide Utilisation, The University of Sheffield, Sheffield, United Kingdom
Soraya Nicole Sluijter: Sustainable Technologies for Industrial Processes, Energy Transition, TNO, Petten, Netherlands

DOI: https://doi.org/10.3389/frsus.2022.1057190
Journal volume & issue: Vol. 3

Abstract

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Dimethyl ether (DME) could have a promising future as a sustainable diesel fuel replacement as it requires only relatively minor engine modifications. It can be produced from renewable H2 and captured CO2 using Power-to-X technologies. To gain support through the EU Renewable Energy Directive, the production and use of CO2-derived DME as a fuel needs to produce emission savings of at least 70% over the petrodiesel alternative. This study assesses the carbon footprint of producing DME via the sorption-enhanced DME synthesis (SEDMES) process and using it as a transport fuel, compared to producing and using fossil-based petrodiesel. The cradle-to-grave (well-to-wheel) carbon footprint of using DME as a transport fuel is found to be 77% lower than for petrodiesel, if offshore wind power is used for H2 synthesis and DME production. If renewable energy is also used for CO2 capture and waste heat is used for the DME production and purification steps, the DME carbon footprint has the potential to be over 90% lower than that of the fossil-fuel comparator.

Published in Frontiers in Sustainability

ISSN: 2673-4524 (Online)
Publisher: Frontiers Media S.A.
Country of publisher: Switzerland
LCC subjects: Social Sciences: Economic theory. Demography
Website: https://www.frontiersin.org/journals/sustainability

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