A Robust, Scalable Platform for the Electrochemical Conversion of CO<sub>2</sub> to Formate: Identifying Pathways to Higher Energy Efficiencies

Chen, Yingying; Vise, Ashlee; Klein, Walter; Cetinbas, Firat C.; Myers, Deborah J.; Smith, Wilson A.; Deutsch, Todd G.; Neyerlin, Kenneth C.

doi:10.1021/acsenergylett.0c00860

Cited by 140 publications

(155 citation statements)

References 72 publications

Supporting

Mentioning

150

Contrasting

Order By: Relevance

“…Finally, further research is still required to overcome current limitations and develop processes with performances that simultaneously optimize all the figures of merit analyzed in this study. In this regard, research efforts should focus on the development of new filter press configurations [ 70 , 71 ] such as the use of a three-compartment electrochemical reactor, bipolar membranes [ 72 ], or working electrode configurations [ 73 ] to enhance the mass transfer of the reagents and products in the counter and working electrode, and simultaneously address the synthesis of innovative electrocatalysts for both cathode [ 74 ] and anode [ 75 ] to reduce the energy consumption in both compartments of the electrochemical reactor.…”

Section: Comparative Study Of the Catalyst Naturementioning

confidence: 99%

Continuous Electrochemical Reduction of CO2 to Formate: Comparative Study of the Influence of the Electrode Configuration with Sn and Bi-Based Electrocatalysts

2020

View full text Add to dashboard Cite

Climate change has become one of the most important challenges in the 21st century, and the electroreduction of CO2 to value-added products has gained increasing importance in recent years. In this context, formic acid or formate are interesting products because they could be used as raw materials in several industries as well as promising fuels in fuel cells. Despite the great number of studies published in the field of the electrocatalytic reduction of CO2 to formic acid/formate working with electrocatalysts of different nature and electrode configurations, few of them are focused on the comparison of different electrocatalyst materials and electrode configurations. Therefore, this work aims at presenting a rigorous and comprehensive comparative assessment of different experimental data previously published after many years of research in different working electrode configurations and electrocatalysts in a continuous mode with a single pass of the inputs through the reactor. Thus, the behavior of the CO2 electroreduction to formate is compared operating with Sn and Bi-based materials under Gas Diffusion Electrodes (GDEs) and Catalyst Coated Membrane Electrodes (CCMEs) configurations. Considering the same electrocatalyst, the use of CCMEs improves the performance in terms of formate concentration and energy consumption. Nevertheless, higher formate rates can be achieved with GDEs because they allow operation at higher current densities of up to 300 mA·cm−2. Bi-based-GDEs outperformed Sn-GDEs in all the figures of merit considered. The comparison also highlights that in CCME configuration, the employ of Bi-based-electrodes enhanced the behavior of the process, increasing the formate concentration by 35% and the Faradaic efficiency by 11%.

show abstract

Section: Comparative Study Of the Catalyst Naturementioning

confidence: 99%

Continuous Electrochemical Reduction of CO2 to Formate: Comparative Study of the Influence of the Electrode Configuration with Sn and Bi-Based Electrocatalysts

2020

View full text Add to dashboard Cite

show abstract

“…2). [21,23,37] We used experimental parameters describing electrochemical reduction towards HCOOand H2 on a Sn electrode because of its ability to selectively produce formate [18,53] and we compared operation with two different gas feed compositions: , 2 = 0.5, corresponding to an equal mixture of CO2 and O2 in the gas feed stream; and , 2 = 0.833, corresponding to a CO2 partial pressure of 1 atm for our model. Current density towards CO2 reduction or H2 production increases exponentially as a function of voltage following Butler-Volmer kinetics ( Fig.…”

Section: Co2 Diffusion and O2 Interphase Transfer Determine Upper Boumentioning

confidence: 99%

“…higher salt and buffer concentrations, higher pHs that enable higher selectivity towards carbon products). [18,54,59] Issues associated with short-lived but toxic byproducts are lessened, [12,28] but simple strategies to directly integrate electrochemical and microbial media with minimal intermediate processing are still necessary. The two-reactor system does have some challenges, however, including increased gas and liquid pumping requirements and the increased number of failure or contamination points.…”

Section: Decoupled Systems Are Likely To Outcompete Integrated Reactorsmentioning

confidence: 99%

“…The choice of redox mediator requires careful consideration: the ideal one should be abundantly available or easily produced electrochemically (eliminating complex organic molecules and inorganic ions), electropositive enough to directly reduce NAD(P)H for efficient energy transfer to cellular metabolism, and highly soluble in liquid water (eliminating H2). [3,5] Formate/ic acid stands out as an especially promising redox mediator because it is readily and specifically produced from CO2 [18][19][20] and multiple natural and engineered formatotrophic growth mechanisms exist in workhorse bacteria. [21][22][23][24][25] Initial scale-up, [26] component integration, [27] and media optimization [28] studies have been performed for MES systems, demonstrating the need for careful attention to process parameters including the gas/liquid mass transfer coefficient (kLa).…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Bioelectrochemical engineering analysis of formate-mediated microbial electrosynthesis

Abel

Clark

2020

Preprint

View full text Add to dashboard Cite

Mediated microbial electrosynthesis (MES) represents a promising strategy for the capture and conversion of CO2 into carbon-based products. We describe the development and application of a comprehensive multiphysics model to analyze a formate-mediated MES reactor. The model shows that this system can achieve a biomass productivity of ∼1.7 g L-1 hr-1 but is limited by a competitive trade-off between O2 gas/liquid mass transfer and CO2 transport to the cathode. Synthetic metabolic strategies are evaluated for formatotrophic growth, which can enable an energy efficiency of ∼21%, a 30% improvement over the Calvin cycle. However, carbon utilization efficiency is only ∼10% in the best cases due to a futile CO2 cycle, so gas recycle will be necessary for greater efficiency. Finally, separating electrochemical and microbial processes into separate reactors enables a higher biomass productivity of ∼2.4 g L-1 hr-1. The mediated MES model and analysis presented here can guide process design for conversion of CO2 into renewable chemical feedstocks.

show abstract

“…The choice of redox mediator requires careful consideration: the ideal one should be abundantly available or easily produced electrochemically (eliminating complex organic molecules and inorganic ions), electropositive enough to directly reduce NAD(P)H for efficient energy transfer to cellular metabolism, and highly soluble in liquid water (eliminating H 2 ) [3,5] . Formate/ic acid stands out as an especially promising redox mediator because it is readily and specifically produced from CO 2 [18–20] and multiple natural and engineered formatotrophic growth mechanisms exist in workhorse bacteria [21–25] …”

Section: Introductionmentioning

confidence: 99%

A Comprehensive Modeling Analysis of Formate‐Mediated Microbial Electrosynthesis**

Abel

Clark

2020

ChemSusChem

View full text Add to dashboard Cite

Mediated microbial electrosynthesis (MES) represents a promising strategy for the capture and conversion of CO2 into carbon‐based products. We describe the development and application of a comprehensive multiphysics model to analyze a formate‐mediated MES reactor. The model shows that this system can achieve a biomass productivity of ∼1.7 g L−1 h−1 but is limited by a competitive trade‐off between O2 gas/liquid mass transfer and CO2 transport to the cathode. Synthetic metabolic strategies are evaluated for formatotrophic growth, which can enable an energy efficiency of ∼21 %, a 30 % improvement over the Calvin cycle. However, carbon utilization efficiency is only ∼10 % in the best cases due to a futile CO2 cycle, so gas recycling will be necessary for greater efficiency. Finally, separating electrochemical and microbial processes into separate reactors enables a higher biomass productivity of ∼2.4 g L−1 h−1. The mediated MES model and analysis presented here can guide process design for conversion of CO2 into renewable chemical feedstocks.

show abstract

A Robust, Scalable Platform for the Electrochemical Conversion of CO₂ to Formate: Identifying Pathways to Higher Energy Efficiencies

Cited by 140 publications

References 72 publications

Continuous Electrochemical Reduction of CO2 to Formate: Comparative Study of the Influence of the Electrode Configuration with Sn and Bi-Based Electrocatalysts

Continuous Electrochemical Reduction of CO2 to Formate: Comparative Study of the Influence of the Electrode Configuration with Sn and Bi-Based Electrocatalysts

Bioelectrochemical engineering analysis of formate-mediated microbial electrosynthesis

A Comprehensive Modeling Analysis of Formate‐Mediated Microbial Electrosynthesis**

Contact Info

Product

Resources

About

A Robust, Scalable Platform for the Electrochemical Conversion of CO2 to Formate: Identifying Pathways to Higher Energy Efficiencies

Cited by 140 publications

References 72 publications

Continuous Electrochemical Reduction of CO2 to Formate: Comparative Study of the Influence of the Electrode Configuration with Sn and Bi-Based Electrocatalysts

Continuous Electrochemical Reduction of CO2 to Formate: Comparative Study of the Influence of the Electrode Configuration with Sn and Bi-Based Electrocatalysts

Bioelectrochemical engineering analysis of formate-mediated microbial electrosynthesis

A Comprehensive Modeling Analysis of Formate‐Mediated Microbial Electrosynthesis**

Contact Info

Product

Resources

About

A Robust, Scalable Platform for the Electrochemical Conversion of CO₂ to Formate: Identifying Pathways to Higher Energy Efficiencies