Integration of CO2 Electrolysers into an Industrial-Scale Process System
Effects of Non-Aqueous Solvents and Gaseous Impurities
A. Sajeev (TU Delft - Large Scale Energy Storage)
W. de Jong – Promotor (TU Delft - Large Scale Energy Storage)
R. Kortlever – Promotor (TU Delft - Large Scale Energy Storage)
M Ramdin – Copromotor (TU Delft - Engineering Thermodynamics)
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Abstract
The increasing dependence on fossil fuels for energy and chemicals has caused a significant rise in atmospheric CO2 concentrations, leading to global warming and ecological imbalances. Electrochemical CO2 reduction (CO2R) has emerged as a promising technology to mitigate CO2 emissions while converting it into valuable chemicals and fuels, such as ethylene, ethanol, and acetic acid. With its compatibility with renewable energy sources, moderate operating conditions, and potential for high selectivity, CO2R is positioned as a key player in the transition toward a carbon-neutral economy. However, challenges such as mass transfer limitations, impurities in industrial CO2 feedstocks, and economic feasibility hinder its large-scale implementation. This thesis aims to address these challenges through experimental studies, process design, and techno-economic analysis. The combined findings also reveal key limitations that must be addressed for large-scale deployment.
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File under embargo until 31-08-2026