Arne Kätelhön
Arne Kätelhön
Institute of Technical Thermodynamics, RWTH Aachen University
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Cited by
Cited by
Climate change mitigation potential of carbon capture and utilization in the chemical industry
A Kätelhön, R Meys, S Deutz, S Suh, A Bardow
Proceedings of the National Academy of Sciences 116 (23), 11187-11194, 2019
Cleaner production of cleaner fuels: wind-to-wheel–environmental assessment of CO 2-based oxymethylene ether as a drop-in fuel
S Deutz, D Bongartz, B Heuser, A Kätelhön, LS Langenhorst, A Omari, ...
Energy & Environmental Science 11 (2), 331-343, 2018
Environmental potential of carbon dioxide utilization in the polyurethane supply chain
N von der Assen, A Sternberg, A Kätelhön, A Bardow
Faraday discussions 183, 291-307, 2015
Techno-economic assessment & life-cycle assessment guidelines for CO2 utilization
A Zimmermann, LJ Müller, A Marxen, K Armstrong, G Buchner, ...
Same or different? Insights on public perception and acceptance of carbon capture and storage or utilization in Germany
K Arning, J Offermann-van Heek, A Linzenich, A Kätelhön, A Sternberg, ...
Energy policy 125, 235-249, 2019
Stochastic technology choice model for consequential life cycle assessment
A Kätelhön, A Bardow, S Suh
Environmental science & technology 50 (23), 12575-12583, 2016
Industry-cost-curve approach for modeling the environmental impact of introducing new technologies in life cycle assessment
A Kätelhön, N von der Assen, S Suh, J Jung, A Bardow
Environmental science & technology 49 (13), 7543-7551, 2015
A guideline for life cycle assessment of carbon capture and utilization
LJ Müller, A Kätelhön, M Bachmann, A Zimmermann, A Sternberg, ...
Towards sustainable elastomers from CO 2: life cycle assessment of carbon capture and utilization for rubbers
R Meys, A Kätelhön, A Bardow
Green chemistry 21 (12), 3334-3342, 2019
CO2 utilisation today: report 2017
A Zimmermann, M Kant, T Strunge, E Tzimas, W Leitner, W Arlt, P Styring, ...
The need for and path to harmonized life cycle assessment and techno‐economic assessment for carbon dioxide capture and utilization
V Sick, K Armstrong, G Cooney, L Cremonese, A Eggleston, G Faber, ...
Energy technology 8 (11), 1901034, 2020
CO2 mitigation costs of catalytic methane decomposition
X Zhang, A Kätelhön, G Sorda, M Helmin, M Rose, A Bardow, R Madlener, ...
Energy 151, 826-838, 2018
The carbon footprint of the carbon feedstock CO 2
LJ Müller, A Kätelhön, S Bringezu, S McCoy, S Suh, R Edwards, V Sick, ...
Energy & Environmental Science 13 (9), 2979-2992, 2020
Life Cycle Assessment for the Design of Chemical Processes, Products, and Supply Chains
J Kleinekorte, L Fleitmann, M Bachmann, A Kätelhön, A Barbosa-Póvoa, ...
Annual Reviews, 2020
Renewable Carbon Feedstock for Polymers-Environmental Benefits from Synergistic Use of Biomass and CO 2
M Bachmann, A Kätelhön, B Winter, R Meys, L Müller, A Bardow
Faraday Discussions, 2021
Konsequenzen einer CO2‐Bepreisung für die chemische Industrie: Erkenntnisse aus einem Bottom‐up‐Modell
C Zibunas, A Kätelhön, R Meys, L Müller, A Bardow
Chemie Ingenieur Technik 92 (9), 1261-1261, 2020
Achieving zero‐carbon emission chemicals and plastics with limited renewable resources
R Meys, L Müller, A Kätelhön, S Suh, A Bardow
Chemie Ingenieur Technik 92 (9), 1169-1169, 2020
CO2 abatement cost curves for the chemical industry: A systems approach
M Bachmann, LJ Müller, A Kätelhön, AD Sternberg, A Bardow
A guideline for standardized life cycle assessment on carbon capture and utilization First experiences and new insights
LJ Müller, T Langhorst, A Kätelhön, M Bachmann, AD Sternberg, ...
The carbon footprint of a chemical industry based on CO2 utilization
A Kätelhön, R Meys, S Deutz, A Bardow
Chemie Ingenieur Technik 90 (9), 1142-1142, 2018
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