TY - JOUR

T1 - A comparative analysis of low-CO2 steam generation technologies

AU - Ziarkash, Waris

AU - Bünning, Sven

AU - Bensmann, Astrid

AU - Baake, Egbert

AU - Hanke-Rauschenbach, Richard

N1 - Publisher Copyright: © 2025 The Author(s)

PY - 2025/4

Y1 - 2025/4

N2 - Considering Europe's imperative to reduce CO2 emissions under the Paris Climate Agreement, there is an urgent need to transition to low-CO2 steam generation in industrial processes. Since steam generation is a major contributor to carbon emissions. This paper presents a comparative analysis across various steam generation technologies, including heat pumps, biogas, biomethane, geothermal, and solar thermal solutions. Employing a multidimensional approach, the study assesses key performance indicators such as steam generation cost, CO2 emissions, CO2 abatement costs, and energy demand to unveil viable alternatives to current fossil-based technologies. The findings identify a clear path for transitioning to low-CO2 steam generation within industrial processes, emphasizing the exploration of high-temperature renewable heat sources, followed by electrification and energy carrier substitution approaches. High-temperature renewable heat sources offer the advantage of achieving an 80–90% reduction in CO2 emissions, with the potential for net cost savings at current CO2 pricing. Addressing challenges associated with each steam generation technology is pivotal to finding the perfect fit for each industrial process and ensuring a successful transition to low-CO2 steam generation.

AB - Considering Europe's imperative to reduce CO2 emissions under the Paris Climate Agreement, there is an urgent need to transition to low-CO2 steam generation in industrial processes. Since steam generation is a major contributor to carbon emissions. This paper presents a comparative analysis across various steam generation technologies, including heat pumps, biogas, biomethane, geothermal, and solar thermal solutions. Employing a multidimensional approach, the study assesses key performance indicators such as steam generation cost, CO2 emissions, CO2 abatement costs, and energy demand to unveil viable alternatives to current fossil-based technologies. The findings identify a clear path for transitioning to low-CO2 steam generation within industrial processes, emphasizing the exploration of high-temperature renewable heat sources, followed by electrification and energy carrier substitution approaches. High-temperature renewable heat sources offer the advantage of achieving an 80–90% reduction in CO2 emissions, with the potential for net cost savings at current CO2 pricing. Addressing challenges associated with each steam generation technology is pivotal to finding the perfect fit for each industrial process and ensuring a successful transition to low-CO2 steam generation.

KW - CO abatement

KW - Comparative analysis

KW - Defossilization approaches

KW - Low-CO steam generation

KW - Renewable heat sources

UR - http://www.scopus.com/inward/record.url?scp=105003220879&partnerID=8YFLogxK

U2 - 10.1016/j.ecmx.2025.101013

DO - 10.1016/j.ecmx.2025.101013

M3 - Letter

AN - SCOPUS:105003220879

VL - 26

JO - Energy Conversion and Management: X

JF - Energy Conversion and Management: X

SN - 2590-1745

M1 - 101013

ER -