Densely Packed, Ultra Small SnO Nanoparticles for Enhanced Activity and Selectivity in Electrochemical CO<sub>2</sub> Reduction

Gu, Junjie; Héroguel, Florent; Luterbacher, Jeremy S.; Hu, Xile

doi:10.1002/ange.201713003

Cited by 59 publications

(20 citation statements)

References 29 publications

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“…A detailed performance comparison between this work and other published Sn‐based electrocatalysts for CO 2 reduction to formate is presented in Figure and Table S1 (Supporting Information). [ 10–14,22a,25,30,31 ] The potential window across −0.5 V to −1.5 V with FE formate over 70% obtained from this work is clearly broader than literature studies that typically display “volcano shape” characteristic. Li et al.…”

Section: Resultsmentioning

confidence: 62%

“…To overcome the intrinsically poor electrocatalytic CO 2 reduction performance of a bulk Sn with a large overpotential and low current density, various material engineering strategies have been applied. This includes nanostructuring of Sn to structures such as metallic Sn quantum sheets, [ 10 ] coralline structured SnO x , [ 11 ] SnO 2 porous nanowires, [ 12 ] ultrasmall SnO, [ 13 ] and SnS 2 nanosheets, [ 14 ] that promotes surface area and active sites toward selective formate production. In addition to alloying or doping with metals, such as copper, [ 15 ] silver, [ 16 ] palladium, [ 17 ] nickel, [ 18 ] positive synergetic impact of doping of a nonmetallic element, such as sulfur [ 19 ] or nitrogen [ 20 ] is another attractive approach toward enhancing formate production.…”

Section: Introductionmentioning

confidence: 99%

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Boosting Formate Production from CO₂ at High Current Densities Over a Wide Electrochemical Potential Window on a SnS Catalyst

2021

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The flow‐cell design offers prospect for transition to commercial‐relevant high current density CO2 electrolysis. However, it remains to understand the fundamental interplay between the catalyst, and the electrolyte in such configuration toward CO2 reduction performance. Herein, the dramatic influence of electrolyte alkalinity in widening potential window for CO2 electroreduction in a flow‐cell system based on SnS nanosheets is reported. The optimized SnS catalyst operated in 1 m KOH achieves a maximum formate Faradaic efficiency of 88 ± 2% at −1.3 V vs reversible hydrogen electrode (RHE) with the current density of ≈120 mA cm−2. Alkaline electrolyte is found suppressing the hydrogen evolution across all potentials which is particularly dominant at the less negative potentials, as well as CO evolution at more negative potentials. This in turn widens the potential window for formate conversion (>70% across −0.5 to −1.5 V vs RHE). A comparative study to SnOx counterpart indicates sulfur also acts to suppress hydrogen evolution, although electrolyte alkalinity resulting in a greater suppression. The boosting of the electrochemical potential window, along with high current densities in SnS derived catalytic system offers a highly attractive and promising route toward industrial‐relevant electrocatalytic production of formate from CO2.

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Section: Resultsmentioning

confidence: 62%

Section: Introductionmentioning

confidence: 99%

Boosting Formate Production from CO₂ at High Current Densities Over a Wide Electrochemical Potential Window on a SnS Catalyst

2021

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“…Increasing the packing density of functional NPs within a limited electrode volume is challenging in electrodes for energy storage [115][116][117][118] and other integrated nanostructures. [57,[119][120][121] Generally, NP-based electrodes with a high mass density cannot be easily achieved by conventional electrode preparation methods such as doctor blading or electrostatic LbL assembly without additional treatments (e.g., the use of a mechanical press or thermal annealing) due to the low-density nature of polymeric (or carbonaceous) materials and electrostatic repulsive forces among NPs with the same charge. [94,101,[122][123][124] On the other hand, it has been reported that in situ LE-LbL assembly can produce densely packed NP multilayers without any NP agglomeration or segregation because the reported approach does not use charged species and/or bulky polymer ligands in organic media.…”

Section: Ligand Exchange Lbl Assembly For Increased Charge Transfer Omentioning

confidence: 99%

Nanoparticle‐Based Electrodes with High Charge Transfer Efficiency through Ligand Exchange Layer‐by‐Layer Assembly

Kwon

Lee

et al. 2020

Advanced Materials

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Electrochemical energy storage devices can be categorized as Faradaic or non-Faradaic charge storage mechanisms depending on the presence of redox charge transfer reactions. [9] Various carbon materials (e.g., porous activated carbon, graphene, and carbon nanotubes (CNTs)) exhibit good charge transfer behavior (i.e., high power) due to their high electrical conductivity. In this case, the charged species (i.e., electric energy) are physically aligned and accumulate along the surface of carbon materials upon potential sweeps, forming an electrical double layer. [10] This charge storage mechanism, which is electrochemical double layer capacitance, has fast charge transfer kinetics and depends on the area of the electrode/electrolyte interface. However, these carbon materials with electrochemical double layer capacitance have intrinsically low-energy density (i.e., a low areal capacitance of ≈30 µF cm −2), [11] limiting their use in high power applications, such as uninterruptible power supplies and load leveling. [12] It has been reported that the immobilization of oxygen functional groups on the surface of carbon materials can induce a Faradaic reaction with specific cations (e.g., Li + or H +) and thus increase the energy density. [13,14] However, carbonbased electrodes have inherently low density (<1 g cm −3) and thus exhibit low volumetric energy density, limiting their practical use in high energy applications, including portable electronic devices and electric vehicles. Recently, various transition metal oxides (TMOs), such as iron oxide, manganese oxide, cobalt oxide, and their mixed oxides, have been investigated for high energy density electrode materials for both pseudocapacitors and batteries due to their high theoretical capacity and large surface-to-volume ratio (i.e., large active surface area in nanomaterial-based electrodes). [15-23] That is, in contrast to capacitive carbon materials, TMO-based electrodes can store large amounts of energy through additional redox reactions (≈2.5 electrons per metal atom of the accessible active surface of transition metal oxides [24]) on/near the electrode surface (pseudocapacitance) or within the bulk of the materials by ion intercalation or phase conversion reactions in battery systems. [25] In addition, the electrochemical performance of TMO-based electrodes can be further improved by controlling their structural parameters, such as particle size, uniformity, crystallinity, crystallite (domain) size, and orientation. [26-33] Organic-ligand-based solution processes of metal and transition metal oxide (TMO) nanoparticles (NPs) have been widely studied for the preparation of electrode materials with desired electrical and electrochemical properties for various energy devices. However, the ligands adsorbed on NPs have a significant effect on the intrinsic properties of materials, thus influencing the performance of bulk electrodes assembled by NPs for energy devices. To resolve these critical drawbacks, numerous approaches have focused on developing unique surface c...

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“…However, the formate and acetate production from the CO 2 RR still remains a scientific challenge 22. Major Sn-based catalysts usually suffer from limited reaction selectivity and a narrow range of active voltage,23–25 although a recent Bi-based catalyst has shown high potential for formate generation 26,27. In addition, very few electrocatalysts perform CO 2 reduction to acetate due to the low activity of C–C coupling 28.…”

Section: Introductionmentioning

confidence: 99%

Cathodized copper porphyrin metal–organic framework nanosheets for selective formate and acetate production from CO₂ electroreduction

et al. 2019

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Densely Packed, Ultra Small SnO Nanoparticles for Enhanced Activity and Selectivity in Electrochemical CO₂ Reduction

Cited by 59 publications

References 29 publications

Boosting Formate Production from CO₂ at High Current Densities Over a Wide Electrochemical Potential Window on a SnS Catalyst

Boosting Formate Production from CO₂ at High Current Densities Over a Wide Electrochemical Potential Window on a SnS Catalyst

Nanoparticle‐Based Electrodes with High Charge Transfer Efficiency through Ligand Exchange Layer‐by‐Layer Assembly

Cathodized copper porphyrin metal–organic framework nanosheets for selective formate and acetate production from CO₂ electroreduction

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Densely Packed, Ultra Small SnO Nanoparticles for Enhanced Activity and Selectivity in Electrochemical CO2 Reduction

Cited by 59 publications

References 29 publications

Boosting Formate Production from CO2 at High Current Densities Over a Wide Electrochemical Potential Window on a SnS Catalyst

Boosting Formate Production from CO2 at High Current Densities Over a Wide Electrochemical Potential Window on a SnS Catalyst

Nanoparticle‐Based Electrodes with High Charge Transfer Efficiency through Ligand Exchange Layer‐by‐Layer Assembly

Cathodized copper porphyrin metal–organic framework nanosheets for selective formate and acetate production from CO2 electroreduction

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Product

Resources

About

Densely Packed, Ultra Small SnO Nanoparticles for Enhanced Activity and Selectivity in Electrochemical CO₂ Reduction

Boosting Formate Production from CO₂ at High Current Densities Over a Wide Electrochemical Potential Window on a SnS Catalyst

Boosting Formate Production from CO₂ at High Current Densities Over a Wide Electrochemical Potential Window on a SnS Catalyst

Cathodized copper porphyrin metal–organic framework nanosheets for selective formate and acetate production from CO₂ electroreduction