Over a 15.9% Solar-to-CO Conversion from Dilute CO<sub>2</sub> Streams Catalyzed by Gold Nanoclusters Exhibiting a High CO<sub>2</sub> Binding Affinity

Kim, Beomil; Seong, Hoeun; Song, Jun; Kwak, Kyuju; Song, Hakhyeon; Tan, Ying Chuan; Park, Gibeom; Oh, Jihun

doi:10.1021/acsenergylett.9b02511

Cited by 119 publications

(110 citation statements)

References 51 publications

(129 reference statements)

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“…8,9 In order to overcome CO 2 mass transport issues, gas-diffusion electrodes (GDEs) have been employed in flow electrolyzers to achieve industrially relevant current densities (>200 mA cm À2 ). [10][11][12] However, transferring these high C 2+ product selectivity performances to GDE-based electrolyzers has been challenging without relying on alkaline electrolyte. [13][14][15] The use of alkaline electrolyte has raised concerns regarding the cost for electrolyte regeneration due to the continuous carbonation formation, which also causes stability issues.…”

Section: Introductionmentioning

confidence: 99%

Modulating Local CO2 Concentration as a General Strategy for Enhancing C−C Coupling in CO2 Electroreduction

Tan

Lee

Song

et al. 2020

Joule

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290

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Local environment plays an important role in steering the reaction pathways in electrochemical CO 2 reduction reaction. Here, we present three approaches to modulate local CO 2 concentration in gas-diffusion electrode flow electrolyzers. Employing monodisperse Cu 2 O nanoparticles as the model catalysts, we demonstrate that providing a moderate local CO 2 concentration is effective in promoting C-C coupling. Ultimately, this study serves as a rational guide to tune CO 2 mass transport in gas-diffusion electrode electrolyzers for the optimal production of valuable multi-carbon molecules.

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Section: Introductionmentioning

confidence: 99%

Modulating Local CO2 Concentration as a General Strategy for Enhancing C−C Coupling in CO2 Electroreduction

Tan

Lee

Song

et al. 2020

Joule

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290

256

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“…The efficiency is higher than recently reported values in a PEC cell without external bias ( Li et al., 2019 ; Andrei et al., 2020 ). Although the efficiency is lower than that reported in photovoltaic-electrolysis (PV-E) system ( Schreier et al., 2015a , 2017 ; Urbain et al., 2017 ; Zhang et al., 2019 ; Kim et al., 2019 ; Cheng et al., 2020 ), the PEC approach integrates the light harvesting and electrochemical process of PV-E process into a single and monolithic device via a direct semiconductor-electrolyte interface, providing potential advantages over the PV-E system in terms of cost and complexity. And it is expected that the STS efficiency of the PEC system could be enhanced further by employing better photoanode with higher photocurrent at the low bias region, which would improve the overlap of J-V curves between photocathode and photoanode.…”

Section: Resultsmentioning

confidence: 98%

Decoupling Strategy for Enhanced Syngas Generation from Photoelectrochemical CO2 Reduction

Chu

Rashid

et al. 2020

iScience

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Summary Photoelectrochemical CO 2 reduction into syngas (a mixture of CO and H 2 ) provides a promising route to mitigate greenhouse gas emissions and store intermittent solar energy into value-added chemicals. Design of photoelectrode with high energy conversion efficiency and controllable syngas composition is of central importance but remains challenging. Herein, we report a decoupling strategy using dual cocatalysts to tackle the challenge based on joint computational and experimental investigations. Density functional theory calculations indicate the optimization of syngas generation using a combination of fundamentally distinctive catalytic sites. Experimentally, by integrating spatially separated dual cocatalysts of a CO-generating catalyst and a H 2 -generating catalyst with GaN nanowires on planar Si photocathode, we report a record high applied bias photon-to-current efficiency of 1.88% and controllable syngas products with tunable CO/H 2 ratios (0–10) under one-sun illumination. Moreover, unassisted solar CO 2 reduction with a solar-to-syngas efficiency of 0.63% is demonstrated in a tandem photoelectrochemical cell.

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“…However, H 2 evolution is expected to dominate at such flow rates. Such findings suggest that low concentration CO 2 gas streams, such as air or flue gas, could be supplied to the cathode at 10 sccm, reducing the amount of CO 2 in the feed, [49] while limiting H 2 evolution by keeping the water content low. In this case, it would be necessary to employ a catalyst that prevents reactions of other components than CO 2 present in air or flue gas, such as the O 2 reduction reaction.…”

Section: Dark Electrochemical Operationmentioning

confidence: 99%

“…Reports of solar-driven CO 2 electrolyzers usually do not mention the CO 2 utilization efficiency, but it may be calculated from the published results and associated operating conditions. [49,52] Our calculations (Table S2, Supporting Information) show that many notable devices [24,26,27,29,31,49,[53][54][55][56] exhibit CO 2 utilization efficiencies below 1%. Given the clear relevance of CO 2 utilization efficiency to the field of (photo-)electrochemical CO 2 reduction, disclosure of this metric should become standard practice for future reports on CO 2 reduction devices.…”

Section: Pec Operationmentioning

confidence: 99%

Monolithic Photoelectrochemical CO₂ Reduction Producing Syngas at 10% Efficiency

Kistler

Cooper

et al. 2021

Advanced Energy Materials

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remain intractable as atmospheric CO 2 concentrations continue to rise.An appreciation for this reality has motivated the development of carbonneutral/negative processes, such as CO 2 -derived fuels/materials production, capable of displacing their carbon-positive counterparts across all economic sectors. CO 2 reduction reactions generally enable a wide range of mixed products, [4] mostly depending on the catalyst, its surface structure, and the electrolyte, [5][6][7][8][9][10][11][12][13][14] often requiring downstream separation. However, carbon monoxide (CO) and its mixture with hydrogen (H 2 ), called synthesis gas (syngas), may be obtained at a selectivity higher than 90%. [15] Syngas is an important precursor in the chemical industry for the production of alcohols, [16] acetic acid, [17] and synthetic hydrocarbon fuels [18,19] but is typically produced from fossil fuels. Alternatively, CO 2 reduction may be driven by electricity from renewable sources, such as solar cells, significantly lowering its carbon footprint. [20][21][22] In solar-driven CO 2 electrolysis (artificial photosynthesis), [23] the solar-to-fuel (STF) efficiency marks a critical figure-of-merit, describing the efficiency with which incident solar energy is incorporated into the chemical bonds of a particular fuel or fuel mixture. Recently, STF efficiencies of 19% at 1 sun illumination intensity have been achieved in devices featuring physically separated photovoltaic (PV) and electrolyzer components. [24][25][26][27][28][29] However, the state of monolithic, photoelectrochemical (PEC) devices has lagged behind the performance of PV-electrolyzers, with monolithic architectures to date displaying peak STF efficiencies of 4.6% for solar CO 2 conversion. [30][31][32] Monolithic designs do not require any wiring between PV and electrocatalytic components during unbiased, PEC operation. [33] The challenge of constructing robust, monolithic PEC devices is compounded by the requisite integration of the PV in the electrolysis compartment, limiting the choice of photoabsorber materials to those resistant to corrosion by the alkaline electrolytes generally employed in CO 2 electrolyzers. [34] Despite such constraints, PEC monoliths may benefit from a more compact device design, enabling lower charge transport losses, and favorable heat-exchange between the PV and the electrolyzer, [33] especially under light concentration. [35] This work describes a monolithic PEC device that converts CO 2 to syngas at a record STF efficiency above 10% (combined solar-to-CO and solar-to-H 2 efficiency). This benchmark represents a doubling in the reported peak efficiency for such Increasing anthropogenic carbon dioxide emissions have prompted the search for photoelectrochemical (PEC) methods of converting CO 2 to useful commodity products, including fuels. Ideally, such PEC approaches will be sustained using only sunlight, water, and CO 2 as energetic and reactant inputs. However, low peak conversion efficiencies (<5%) have made commercialization of fully-integrated...

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Over a 15.9% Solar-to-CO Conversion from Dilute CO₂ Streams Catalyzed by Gold Nanoclusters Exhibiting a High CO₂ Binding Affinity

Cited by 119 publications

References 51 publications

Modulating Local CO2 Concentration as a General Strategy for Enhancing C−C Coupling in CO2 Electroreduction

Modulating Local CO2 Concentration as a General Strategy for Enhancing C−C Coupling in CO2 Electroreduction

Decoupling Strategy for Enhanced Syngas Generation from Photoelectrochemical CO2 Reduction

Monolithic Photoelectrochemical CO₂ Reduction Producing Syngas at 10% Efficiency

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Over a 15.9% Solar-to-CO Conversion from Dilute CO2 Streams Catalyzed by Gold Nanoclusters Exhibiting a High CO2 Binding Affinity

Cited by 119 publications

References 51 publications

Modulating Local CO2 Concentration as a General Strategy for Enhancing C−C Coupling in CO2 Electroreduction

Modulating Local CO2 Concentration as a General Strategy for Enhancing C−C Coupling in CO2 Electroreduction

Decoupling Strategy for Enhanced Syngas Generation from Photoelectrochemical CO2 Reduction

Monolithic Photoelectrochemical CO2 Reduction Producing Syngas at 10% Efficiency

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Product

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Over a 15.9% Solar-to-CO Conversion from Dilute CO₂ Streams Catalyzed by Gold Nanoclusters Exhibiting a High CO₂ Binding Affinity

Monolithic Photoelectrochemical CO₂ Reduction Producing Syngas at 10% Efficiency