Simulation‐based guidance for improving CO2${\rm CO}_{2}$ reduction on silver gas diffusion electrodes

Heßelmann, Matthias; Bräsel, Berinike Clara; Keller, Robert; Weßling, Matthias

doi:10.1002/elsa.202100160

Cited by 18 publications

(20 citation statements)

References 71 publications

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Section: Engineering Aspects—scale‐up and Modeling Of Gde‐based Proce...mentioning

confidence: 99%

“…They concluded that the decoupling of the electrochemical and microbial processes into separate reactors overcomes this limitation. Further modeling includes for example, the model-based improvement of GDE(Heßelmann et al, 2022), model-based upscaling of GDE based CO 2 -reduction systems (Z Yang et al, 2021). and a multi-criteria optimization of H 2 O 2 synthesis in GDE(von Kurnatowski & Bortz, 2021).6 | CONCLUSION AND OUTLOOKFor improvement of established production processes as well as development of new sustainable and biobased synthesis routes within a circular economy, the combination of biotechnology and electrochemistry is a powerful tool.…”

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confidence: 99%

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Application of gas diffusion electrodes in bioeconomy: An update

Stöckl

Lange

Izadi

et al. 2023

Biotech & Bioengineering

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The transition of today's fossil fuel based chemical industry toward sustainable production requires improvement of established production processes as well as development of new sustainable and bio-based synthesis routes within a circular economy. Thereby, the combination of electrochemical and biotechnological advantages in such routes represents one important keystone. For the electrochemical generation of reactants from gaseous substrates such as O 2 or CO 2 , gas diffusion electrodes (GDE) represent the electrodes of choice since they overcome solubility-based mass transport limitations. Within this article, we illustrate the architecture, function principle and fabrication of GDE. We highlight the application of GDE for conversion of CO 2 using abiotic catalysts for subsequent biosynthesis as well as the application of microbial catalysts at GDE for CO 2 conversion. The reduction of oxygen at GDE is summarized for the application of oxygen depolarized cathodes in microbial fuel cells and generation of H 2 O 2 to drive enzymatic reactions. Finally, engineering aspects such as scale-up and the modeling of GDE-based processes are described. This review presents an update on the application of GDE in bio-based production systems and emphasizes their large potential for sustainable development of new pathways in bioeconomy.bioeconomy, C1-biotechnology, CO 2 conversion, electrobiotechnology, gas diffusion electrode, hydrogen peroxide dependent enzymes | INTRODUCTIONThe combination of electrochemical and microbial as well as enzymatic reactions is well-established in the field of biosensors (Bedendi et al., 2022). In bioeconomy in general, this combination is believed to be highly effective to optimize established processes or to setup new production routes (Harnisch & Urban, 2018). Often, the high selectivity of the biocatalysts is combined with a high energy efficiency of the electrochemical reaction step. Common examples are the electrochemical substitution or regeneration of cofactors

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Section: Engineering Aspects—scale‐up and Modeling Of Gde‐based Proce...mentioning

confidence: 99%

mentioning

confidence: 99%

Application of gas diffusion electrodes in bioeconomy: An update

Stöckl

Lange

Izadi

et al. 2023

Biotech & Bioengineering

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“…[9,10] In the field of GDEs for CO 2 reduction, substantial work has been presented in the literature on catalyst design, [11,12] GDE composition, [13][14][15] and process studies on laboratory scale. [16][17][18] We recently presented a detailed model that predicts speciation and pH gradients for the reduction of CO 2 , [19] and investigated wetting in porous networks comprised of surfaces with different zeta potentials. [20] Although the fundamental Utilizing carbon dioxide (CO 2 ) as a resource for carbon monoxide (CO) production using renewable energy requires electrochemical reactors with gas diffusion electrodes that maintain a stable and highly reactive gas/liquid/solid interface.…”

Section: Doi: 101002/smll202204012mentioning

confidence: 99%

“…Indirect influences on the fluorescent lifetime might be changes in the local pH value, or the formation of ionic species on the electrodes as is often observed with CO 2 electroreduction. [19,42,43] This reaction visualization via FLIM allows the accurate identification of active areas of the GDE structure.…”

Section: Visualizing Of Reactions Inside a Gdementioning

confidence: 99%

Micromodel of a Gas Diffusion Electrode Tracks In‐Operando Pore‐Scale Wetting Phenomena

Kalde

Großeheide

Brosch

et al. 2022

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Utilizing carbon dioxide (CO2) as a resource for carbon monoxide (CO) production using renewable energy requires electrochemical reactors with gas diffusion electrodes that maintain a stable and highly reactive gas/liquid/solid interface. Very little is known about the reasons why gas diffusion electrodes suffer from unstable long‐term operation. Often, this is associated with flooding of the gas diffusion electrode (GDE) within a few hours of operation. A better understanding of parameters influencing the phase behavior at the electrolyte/electrode/gas interface is necessary to increase the durability of GDEs. In this work, a microfluidic structure with multi‐scale porosity featuring heterogeneous surface wettability to realistically represent the behavior of conventional GDEs is presented. A gas/liquid/solid phase boundary was established within a conductive, highly porous structure comprising a silver catalyst and Nafion binder. Inoperando visualization of wetting phenomena was performed using confocal laser scanning microscopy (CLSM). Non‐reversible wetting, wetting of hierarchically porous structures and electrowetting were observed and analyzed. Fluorescence lifetime imaging microscopy (FLIM) enabled the observation of reactions on the model electrode surface. The presented methodology enables the systematic evaluation of spatio‐temporally evolving wetting phenomena as well as species characterization for novel catalyst materials under realistic GDE configurations and process parameters.

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“…Industrial CO 2 electrolyzers will require integration with upstream and downstream chemical processes. − To plan for these deployments, chemical simulations must be able to accurately predict CO 2 electrolyzer behavior at relevant scales. Multiphysics simulations have been used to estimate reaction kinetics, model the pH distribution, improve CO 2 utilization, identify failure mechanisms, and provide a better fundamental understanding of lab-scale reactors. − Most simulations of CO 2 electrolysis are one-dimensional simulations focused on single-carbon products with cell sizes <10 cm 2 (Table S5). Unfortunately, the computational expense of these simulations becomes prohibitive as the reactor grows due to the number of physical parameters and scales involved. , Models have been developed for CO 2 electrolyzers which are useful in predicting specific elements of electrolyzer performance (e.g., cell voltage) but do not produce a complete mass and energy balance .…”

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confidence: 99%

Pilot-Scale CO₂ Electrolysis Enables a Semi-empirical Electrolyzer Model

et al. 2023

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Carbon dioxide (CO 2 ) electrolysis powered with renewable electricity can help close the carbon cycle by converting emissions into chemicals and fuels. Two key advancements are required to bridge the technological gaps for industrial implementation: pilot plant demonstrations with detailed performance data; and chemical engineering process models built and tested with lab-and pilot-scale data. Here, we develop a semi-empirical electrolyzer model in Aspen Custom Modeler which is trained on a 5 cm 2 lab-scale CO 2 electrolyzer. We then scale to a pilot-scale 800 cm 2 single cell and 10 × 800 cm 2 stack and use the results to validate the model; at 100 mA cm −2 , the model can predict six of seven cell performance metrics within 16% absolute error and three of five stack metrics within 11% absolute error. With the combination of the electrolyzer model and the pilot-scale data, this work provides the prerequisites for further scaling of CO 2 electrolysis.

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Simulation‐based guidance for improving CO2${\rm CO}_{2}$ reduction on silver gas diffusion electrodes

Cited by 18 publications

References 71 publications

Application of gas diffusion electrodes in bioeconomy: An update

Application of gas diffusion electrodes in bioeconomy: An update

Micromodel of a Gas Diffusion Electrode Tracks In‐Operando Pore‐Scale Wetting Phenomena

Pilot-Scale CO₂ Electrolysis Enables a Semi-empirical Electrolyzer Model

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Simulation‐based guidance for improving CO2${\rm CO}_{2}$ reduction on silver gas diffusion electrodes

Cited by 18 publications

References 71 publications

Application of gas diffusion electrodes in bioeconomy: An update

Application of gas diffusion electrodes in bioeconomy: An update

Micromodel of a Gas Diffusion Electrode Tracks In‐Operando Pore‐Scale Wetting Phenomena

Pilot-Scale CO2 Electrolysis Enables a Semi-empirical Electrolyzer Model

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Pilot-Scale CO₂ Electrolysis Enables a Semi-empirical Electrolyzer Model