Your search keyword '"CO2 reduction reaction"' showing total 31 results

1. Reaction Pathway Regulation for Gaseous and Liquid Products of Electrocatalytic CO2 Reduction under Adsorbate Interactions.

Author

Hu, Feng, Xu, Xiaoqian, Sun, Yajie, Hu, Chuan, Shen, Shuning, Wang, Ying, Gong, Lei, Li, Linlin, and Peng, Shengjie

Subjects

*GIBBS' free energy, *ACTIVATION energy, *ELECTROLYTIC reduction, *THERMODYNAMICS, *TRANSITION metals

Abstract

Halide anion adsorption on transition metals can improve the performance of electrochemical CO2 reduction reaction (CO2RR), while the specific reaction mechanisms governing selective CO2RR pathways remain unclear. In this study, we reveal for the first time the distinct pathway switching between gaseous (CO) and liquid products (formate and ethanol) on the well‐defined Ag−Cu nanostructures with controlled chlorination. We show that CO2 conversion to CO on Ag/AgCl can be tuned by adjusting the thickness of AgCl layer, achieving a high selectivity over a broad potential range in a 0.5 M KHCO3 using flow cell. In contrast, the optimized Cl−Ag/Cu system enables the conversion of CO2 into liquid products including formate and ethanol with a total Faradaic efficiency (FE) nearing 100 %, delivering high current densities of 136.3 and 20.8 mA cm−2 at −1.3 V, respectively. In situ infrared experiments and theoretical calculations indicate that the lateral adsorbate of *OCHO intermediate facilitates the thermodynamics of both the CO pathway on Cl−Ag(111) and the formate pathway on Cl−Ag/Cu(111) by reducing Gibbs free energy barriers of each potential‐limit step. This work uncovers the role of chlorination in the tuning of C‐bound or O‐bound intermediates during CO2RR on Ag−Cu catalysts, determining the reaction pathway under lateral adsorbate effects. [ABSTRACT FROM AUTHOR]

Published

2024

2. A Regenerable Bi‐Based Catalyst for Efficient and Stable Electrochemical CO2 Reduction to Formate at Industrial Current Densities.

Author

Liu, Hong, Bai, Ye, Wu, Meng, Yang, Yingchen, Wang, Yaoxuan, Li, Longhua, Hao, Jinhui, Yan, Weicheng, and Shi, Weidong

Subjects

*CARBON dioxide reduction, *ACTIVATION energy, *CYCLIC voltammetry, *RAMAN spectroscopy, *ENERGY consumption

Abstract

Renewable electricity shows immense potential as a driving force for the carbon dioxide reduction reaction (CO2RR) in production of formate (HCOO−) at industrial current density, providing a promising path for value‐added chemicals and chemical manufacturing. However, achieving high selectivity and stable production of HCOO− at industrial current density remains a challenge. Here, we present a robust Bi0.6Cu0.4 NSs catalyst capable of regenerating necessary catalytic core (Bi−O) through cyclic voltammetry (CV) treatment. Notably, at 260 mA cm−2, faradaic efficiency of HCOO− reaches an exceptional selectivity to 99.23 %, maintaining above 90 % even after 400 h, which is longest reaction time reported at the industrial current density. Furthermore, in stability test, the catalyst was constructed by CV reconstruction to achieve stable and efficient production of HCOO−. In 20 h reaction test, the catalyst has a rate of HCOO− production of 13.24 mmol m−2 s−1, a HCOO− concentration of 1.91 mol L−1, and an energy consumption of 129.80 kWh kmol−1. In situ Raman spectroscopy reveals the formation of Bi−O structure during the gradual transformation of catalyst from Bi0.6Cu0.4 NBs to Bi0.6Cu0.4 NSs. Theoretical studies highlight the pivotal role of Bi−O structure in modifying the adsorption behavior of reaction intermediates, which further reduces energy barrier for *OCHO conversion in CO2RR. [ABSTRACT FROM AUTHOR]

Published

2024

3. Quantifying Interface‐Performance Relationships in Electrochemical CO2 Reduction through Mixed‐Dimensional Assembly of Nanocrystal‐on‐Nanowire Superstructures.

Author

Chen, Hushui, Xiao, Taishi, Xia, Yan, Song, Hengyao, Xi, Xiangyun, Huang, Xianwu, Yang, Dong, Li, Tongtao, Sun, Zhengzong, and Dong, Angang

Subjects

*HETEROGENEOUS catalysts, *CATALYTIC activity, *ELECTROLYTIC reduction, *ELECTROCATALYSTS, *NANOCRYSTALS

Abstract

Fine‐tuning the interfacial sites within heterogeneous catalysts is pivotal for unravelling the intricate structure–property relationship and optimizing their catalytic performance. Herein, a simple and versatile mixed‐dimensional assembly approach is proposed to create nanocrystal‐on‐nanowire superstructures with precisely adjustable numbers of biphasic interfaces. This method leverages an efficient self‐assembly process in which colloidal nanocrystals spontaneously organize onto Ag nanowires, driven by the solvophobic effect. Importantly, varying the ratio of the two components during assembly allows for accurate control over both the quantity and contact perimeter of biphasic interfaces. As a proof‐of‐concept demonstration, a series of Au‐on‐Ag superstructures with varying numbers of Au/Ag interfaces are constructed and employed as electrocatalysts for electrochemical CO2‐to‐CO conversion. Experimental results reveal a logarithmic linear relationship between catalytic activity and the number of Au/Ag interfaces per unit mass of Au‐on‐Ag superstructures. This work presents a straightforward approach for precise interface engineering, paving the way for systematic exploration of interface‐dependent catalytic behaviors in heterogeneous catalysts. [ABSTRACT FROM AUTHOR]

Published

2024

4. Steering the Site Distance of Atomic Cu−Cu Pairs by First‐Shell Halogen Coordination Boosts CO2‐to‐C2 Selectivity.

Author

Ma, Fengya, Zhang, Pengfang, Zheng, Xiaobo, Chen, Liang, Li, Yunrui, Zhuang, Zechao, Fan, Yameng, Jiang, Peng, Zhao, Hui, Zhang, Jiawei, Dong, Yuming, Zhu, Yongfa, Wang, Dingsheng, and Wang, Yao

Subjects

*ATTENUATED total reflectance, *INFRARED absorption, *ACTIVATION energy, *INFRARED spectroscopy, *PROTON transfer reactions, *ELECTROLYTIC reduction

Abstract

Electrocatalytic reduction of CO2 into C2 products of high economic value provides a promising strategy to realize resourceful CO2 utilization. Rational design and construct dual sites to realize the CO protonation and C−C coupling to unravel their structure‐performance correlation is of great significance in catalysing electrochemical CO2 reduction reactions. Herein, Cu−Cu dual sites with different site distance coordinated by halogen at the first‐shell are constructed and shows a higher intramolecular electron redispersion and coordination symmetry configurations. The long‐range Cu−Cu (Cu−I−Cu) dual sites show an enhanced Faraday efficiency of C2 products, up to 74.1 %, and excellent stability. In addition, the linear relationships that the long‐range Cu−Cu dual sites are accelerated to C2H4 generation and short‐range Cu−Cu (Cu−Cl−Cu) dual sites are beneficial for C2H5OH formation are disclosed. In situ electrochemical attenuated total reflection surface enhanced infrared absorption spectroscopy, in situ Raman and theoretical calculations manifest that long‐range Cu−Cu dual sites can weaken reaction energy barriers of CO hydrogenation and C−C coupling, as well as accelerating deoxygenation of *CH2CHO. This study uncovers the exploitation of site‐distance‐dependent electrochemical properties to steer the CO2 reduction pathway, as well as a potential generic tactic to target C2 synthesis by constructing the desired Cu−Cu dual sites. [ABSTRACT FROM AUTHOR]

Published

2024

5. Precise Synthesis of Dual‐Single‐Atom Electrocatalysts through Pre‐Coordination‐Directed in Situ Confinement for CO2 Reduction.

Author

Rao, Peng, Han, Xingqi, Sun, Haochen, Wang, Fangyuan, Liang, Ying, Li, Jing, Wu, Daoxiong, Shi, Xiaodong, Kang, Zhenye, Miao, Zhengpei, Deng, Peilin, and Tian, Xinlong

Subjects

*BIMETALLIC catalysts, *METAL phthalocyanines, *ELECTROCATALYSTS, *CATALYSTS, *CARBON dioxide

Abstract

Dual‐single‐atom catalysts (DSACs) are the next paradigm shift in single‐atom catalysts because of the enhanced performance brought about by the synergistic effects between adjacent bimetallic pairs. However, there are few methods for synthesizing DSACs with precise bimetallic structures. Herein, a pre‐coordination strategy is proposed to precisely synthesize a library of DSACs. This strategy ensures the selective and effective coordination of two metals via phthalocyanines with specific coordination sites, such as −F− and −OH−. Subsequently, in situ confinement inhibits the migration of metal pairs during high‐temperature pyrolysis, and obtains the DSACs with precisely constructed metal pairs. Despite changing synthetic parameters, including transition metal centers, metal pairs, and spatial geometry, the products exhibit similar atomic metal pairs dispersion properties, demonstrating the universality of the strategy. The pre‐coordination strategy synthesized DSACs shows significant CO2 reduction reaction performance in both flow‐cell and practical rechargeable Zn‐CO2 batteries. This work not only provides new insights into the precise synthesis of DSACs, but also offers guidelines for the accelerated discovery of efficient catalysts. [ABSTRACT FROM AUTHOR]

Published

2024

6. Gapped and Rotated Grain Boundary Revealed in Ultra‐Small Au Nanoparticles for Enhancing Electrochemical CO2 Reduction.

Author

Wang, Wenying, Chen, Dong, Fung, Victor, Zhuang, Shengli, Zhou, Yue, Wang, Chengming, Bian, Guoqing, Zhao, Yan, Xia, Nan, Li, Jin, Deng, Haiteng, Liao, Lingwen, Yang, Jun, Jiang, De‐en, and Wu, Zhikun

Abstract

Although gapped grain boundaries have often been observed in bulk and nanosized materials, and their crucial roles in some physical and chemical processes have been confirmed, their acquisition at ultrasmall nanoscale presents a significant challenge. To date, they had not been reported in metal nanoparticles smaller than 2 nm owing to the difficulty in characterization and the high instability of grain boundary (GB) atoms. Herein, we have successfully developed a synthesis method for producing a novel chiral nanocluster Au78(TBBT)40 (TBBT=4‐tert‐butylphenylthiolate) with a 26‐atom gapped and rotated GB. This nanocluster was precisely characterized using single‐crystal X‐ray crystallography and mass spectrometry. Additionally, an offset atomic defect linked to the peripheral Au(TBBT)2 staple was found in the structure. Comparing it to similarly face‐centered cubic‐structured Au36(TBBT)24, Au44(TBBT)28, Au52(TBBT)32, Au92(TBBT)44, and ~5 nm nanocrystals, the bridging Au78(TBBT)40 nanocluster exhibited higher catalytic activity in the electroreduction of CO2 to CO. This enhanced activity was explained through density functional theory calculations and X‐ray photoelectron spectroscopy analysis, which highlight the impact of GBs and point defects on the surface properties of metal nanoclusters in balancing intermediate adsorption and product desorption. [ABSTRACT FROM AUTHOR]

Published

2024

7. Cobalt‐Doped Bismuth Nanosheet Catalyst for Enhanced Electrochemical CO2 Reduction to Electrolyte‐Free Formic Acid.

Author

Nankya, Rosalynn, Xu, Yuting, Elgazzar, Ahmad, Zhu, Peng, Wi, Tae‐Ung, Qiu, Chang, Feng, Yuge, Che, Fanglin, and Wang, Haotian

Subjects

*FORMIC acid, *ELECTROLYTIC reduction, *BISMUTH, *SOLID electrolytes, *CARBON offsetting, *LIQUID fuels, *URANIUM-lead dating

Abstract

Electrochemical carbon dioxide (CO2) reduction reaction (CO2RR) to valuable liquid fuels, such as formic acid/formate (HCOOH/HCOO−) is a promising strategy for carbon neutrality. Enhancing CO2RR activity while retaining high selectivity is critical for commercialization. To address this, we developed metal‐doped bismuth (Bi) nanosheets via a facile hydrolysis method. These doped nanosheets efficiently generated high‐purity HCOOH using a porous solid electrolyte (PSE) layer. Among the evaluated metal‐doped Bi catalysts, Co‐doped Bi demonstrated improved CO2RR performance compared to pristine Bi, achieving ~90 % HCOO− selectivity and boosted activity with a low overpotential of ~1.0 V at a current density of 200 mA cm−2. In a solid electrolyte reactor, Co‐doped Bi maintained HCOOH Faradaic efficiency of ~72 % after a 100‐hour operation under a current density of 100 mA cm−2, generating 0.1 M HCOOH at 3.2 V. Density functional theory (DFT) results revealed that Co‐doped Bi required a lower applied potential for HCOOH generation from CO2, due to stronger binding energy to the key intermediates OCHO* compared to pure Bi. This study shows that metal doping in Bi nanosheets modifies the chemical composition, element distribution, and morphology, improving CO2RR catalytic activity performance by tuning surface adsorption affinity and reactivity. [ABSTRACT FROM AUTHOR]

Published

2024

8. CO Intermediate‐Assisted Dynamic Cu Sintering During Electrocatalytic CO2 Reduction on Cu−N−C Catalysts.

Author

Qin, Yanyang, Zhao, Wenshan, Xia, Chenfeng, Yu, Li‐Juan, Song, Fei, Zhang, Jianrui, Wu, Tiantian, Cao, Rui, Ding, Shujiang, Xia, Bao Yu, and Su, Yaqiong

Subjects

*ELECTROLYTIC reduction, *COPPER, *STRUCTURE-activity relationships, *CATALYSTS, *SINTERING, *DENSITY functional theory

Abstract

The electrochemical CO2 reduction reaction (eCO2RR) to multicarbon products has been widely recognized for Cu‐based catalysts. However, the structural changes in Cu‐based catalysts during the eCO2RR pose challenges to achieving an in‐depth understanding of the structure–activity relationship, thereby limiting catalyst development. Herein, we employ constant‐potential density functional theory calculations to investigate the sintering process of Cu single atoms of Cu−N−C single‐atom catalysts into clusters under eCO2RR conditions. Systematic constant‐potential ab initio molecular dynamics simulations revealed that the leaching of Cu−(CO)x moieties and subsequent agglomeration into clusters can be facilitated by synergistic adsorption of H and eCO2RR intermediates (e.g. CO). Increasing the Cu2+ concentration or the applied potential can efficiently suppress Cu sintering. Both microkinetic simulations and experimental results further confirm that sintered Cu clusters play a crucial role in generating C2 products. These findings provide significant insights into the dynamic evolution of Cu‐based catalysts and the origin of their activity toward C2 products during the eCO2RR. [ABSTRACT FROM AUTHOR]

Published

2024

9. Improving the Accuracy of Modelling CO2 Electroreduction on Copper Using Many‐Body Perturbation Theory

Author

Wei, Ziyang and Sautet, Philippe

Subjects

Chemical Sciences, Theoretical and Computational Chemistry, CO2 Reduction Reaction, Electrocatalysis, Many-Body Perturbation Theory, Solvation, Organic Chemistry, Chemical sciences

Abstract

Copper (Cu) remains the most important metal catalyst for the carbon dioxide reduction reaction (CO2 RR) into C2 products. Due to limited evidence from in situ experiments, mechanistic studies are often performed in the framework of density functional theory (DFT), using functionals at the generalized gradient approximation (GGA) level, which have fundamental difficulties to correctly describe CO adsorption and surface stability. We employ the adiabatic connection fluctuation dissipation theorem within the random phase approximation (RPA), in combination with the linearized Poisson-Boltzmann equation to describe solvation effects, to investigate the mechanism of CO2 RR on the Cu(100) facet. Qualitatively different from the DFT-GGA results, RPA results propose the formation of *OCCHO as the potential determining step towards C2 products. The results suggest that it is important to use more accurate methods like RPA when modeling reactions involving multiple CO-related species like CO2 RR.

Published

2022

10. The Role of Phase Mixing Degree in Promoting C−C Coupling in Electrochemical CO2 Reduction Reaction on Cu‐based Catalysts.

Author

Wang, Yinuo, Yang, Fei, Xu, Hongming, Jang, Juhee, Delmo, Ernest P., Qiu, Xiaoyi, Ying, Zhehan, Gao, Ping, Zhu, Shangqian, Gu, M. Danny, and Shao, Minhua

Subjects

*COUPLING reactions (Chemistry), *ELECTROLYTIC reduction, *CATALYSTS, *INFRARED absorption, *INFRARED spectroscopy, *COPPER

Abstract

Cu‐based catalysts have been identified as the most promising candidates for generation of C2+ products in electrochemical CO2 reduction reaction. Defect engineering in catalysts is a widely employed strategy for promoting C−C coupling on Cu. However, comprehensive understanding of defect structure‐to‐activity relationship has not been obtained. In this study, controllable defects generation is achieved, which leads to a series of Cu‐based catalysts with various phase mixing degrees. It is observed that the Faradaic efficiency toward C2+ products increases with the phase mixing degree, reaching 81 % at maximum. In situ infrared absorption spectroscopy reveals that the catalysts with higher phase mixing degree tend to form *CO more easily and possess higher retention of *CO under high overpotential window, thereby promoting C−C coupling. This work sheds new light on the relationship between defects and C−C coupling, and the rational developed of more advanced Cu‐base catalysts. [ABSTRACT FROM AUTHOR]

Published

2024

11. Uncovering Photoelectronic and Photothermal Effects in Plasmon‐Mediated Electrocatalytic CO2 Reduction.

Author

Wei, Yan, Mao, Zijie, Jiang, Tian‐Wen, Li, Hong, Ma, Xian‐Yin, Zhan, Chao, and Cai, Wen‐Bin

Subjects

*PHOTOTHERMAL effect, *SURFACE plasmon resonance, *INTERFACIAL reactions, *INFRARED absorption, *ELECTROCATALYSIS

Abstract

Plasmon‐mediated electrocatalysis that rests on the ability of coupling localized surface plasmon resonance (LSPR) and electrochemical activation, emerges as an intriguing and booming area. However, its development seriously suffers from the entanglement between the photoelectronic and photothermal effects induced by the decay of plasmons, especially under the influence of applied potential. Herein, using LSPR‐mediated CO2 reduction on Ag electrocatalyst as a model system, we quantitatively uncover the dominant photoelectronic effect on CO2 reduction reaction over a wide potential window, in contrast to the leading photothermal effect on H2 evolution reaction at relatively negative potentials. The excitation of LSPR selectively enhances the CO faradaic efficiency (17‐fold at −0.6 VRHE) and partial current density (100‐fold at −0.6 VRHE), suppressing the undesired H2 faradaic efficiency. Furthermore, in situ attenuated total reflection‐surface enhanced infrared absorption spectroscopy (ATR‐SEIRAS) reveals a plasmon‐promoted formation of the bridge‐bonded CO on Ag surface via a carbonyl‐containing C1 intermediate. The present work demonstrates a deep mechanistic understanding of selective regulation of interfacial reactions by coupling plasmons and electrochemistry. [ABSTRACT FROM AUTHOR]

Published

2024

12. A Sulfur‐Doped Copper Catalyst with Efficient Electrocatalytic Formate Generation during the Electrochemical Carbon Dioxide Reduction Reaction.

Author

Wang, Yinuo, Xu, Hongming, Liu, Yushen, Jang, Juhee, Qiu, Xiaoyi, Delmo, Ernest P., Zhao, Qinglan, Gao, Ping, and Shao, Minhua

Subjects

*ELECTROLYTIC reduction, *COPPER catalysts, *CARBON dioxide reduction, *INTERSTITIAL hydrogen generation, *NONMETALS, *COPPER, *CRYSTAL grain boundaries

Abstract

Catalysts involving post‐transition metals have shown almost invincible performance on generating formate in electrochemical CO2 reduction reaction (CO2RR). Conversely, Cu without post‐transition metals has struggled to achieve comparable activity. In this study, a sulfur (S)‐doped‐copper (Cu)‐based catalyst is developed, exhibiting excellent performance in formate generation with a maximum Faradaic efficiency of 92 % and a partial current density of 321 mA cm−2. Ex situ structural elucidations reveal the presence of abundant grain boundaries and high retention of S−S bonds from the covellite phase during CO2RR. Furthermore, thermodynamic calculations demonstrate that S−S bonds can moderate the binding energies with various intermediates, further improving the activity of the formate pathway. This work is significant in modifying a low‐cost catalyst (Cu) with a non‐metallic element (S) to achieve comparable performance to mainstream catalysts for formate generation in industrial grade. [ABSTRACT FROM AUTHOR]

Published

2024

13. Boosting Electrocatalytic Carbon Dioxide Reduction via Self‐Relaxation of Asymmetric Coordination in Fe‐Based Single Atom Catalyst.

Author

Jin, Zhaoyong, Jiao, Dongxu, Dong, Yilong, Liu, Lin, Fan, Jinchang, Gong, Ming, Ma, Xingcheng, Wang, Ying, Zhang, Wei, Zhang, Lei, Gen Yu, Zhi, Voiry, Damien, Zheng, Weitao, and Cui, Xiaoqiang

Abstract

Addressing the limitations arising from the consistent catalytic behavior observed for various intermediates during the electrochemical carbon dioxide reduction reaction (CO2RR) poses a significant challenge in the optimization of catalytic activity. In this study, we aimed to address this challenge by constructing an asymmetric coordination Fe single atom catalyst (SCA) with a dynamically evolved structure. Our catalyst, consisting of a Fe atom coordinated with one S atom and three N atoms (Fe−S1N3), exhibited exceptional selectivity (CO Faradaic efficiency of 99.02 %) and demonstrated a high intrinsic activity (TOF of 7804.34 h−1), and remarkable stability. Using operando XAFS spectra and Density Functional Theory (DFT) calculations, we elucidated the self‐relaxation of geometric distortion and dynamic evolution of bond lengths within the catalyst. These structure changes enabled independent regulation of the *COOH and *CO intermediate adsorption energies, effectively breaking the linear scale relationship and enhancing the intrinsic activity of CO2RR. This study provides valuable insights into the dynamic evolution of SACs and paves the way for targeted catalyst designs aimed to disrupt the linear scaling relationships. [ABSTRACT FROM AUTHOR]

Published

2024

14. Polymer Modification Strategy to Modulate Reaction Microenvironment for Enhanced CO2 Electroreduction to Ethylene.

Author

Deng, Ting, Jia, Shuaiqiang, Chen, Chunjun, Jiao, Jiapeng, Chen, Xiao, Xue, Cheng, Xia, Wei, Xing, Xueqing, Zhu, Qinggong, Wu, Haihong, He, Mingyuan, and Han, Buxing

Subjects

*POLYTEF, *HYDROPHOBIC surfaces, *STANDARD hydrogen electrode, *CARBON dioxide reduction, *ELECTROLYTIC reduction, *ETHYLENE, *SUPERHYDROPHOBIC surfaces

Abstract

Modulation of the microenvironment on the electrode surface is one of the effective means to improve the efficiency of electrocatalytic carbon dioxide reduction (eCO2RR). To achieve high conversion rates, the phase boundary at the electrode surface should be finely controlled to overcome the limitation of CO2 solubility in the aqueous electrolyte. Herein, we developed a simple and efficient method to structure electrocatalyst with a superhydrophobic surface microenvironment by one‐step co‐electrodeposition of Cu and polytetrafluoroethylene (PTFE) on carbon paper. The super‐hydrophobic Cu‐based electrode displayed a high ethylene (C2H4) selectivity with a Faraday efficiency (FE) of 67.3 % at −1.25 V vs. reversible hydrogen electrode (RHE) in an H‐type cell, which is 2.5 times higher than a regular Cu electrode without PTFE. By using PTFE as a surface modifier, the activity of eCO2RR is enhanced and water (proton) adsorption is inhibited. This strategy has the potential to be applied to other gas‐conversion electrocatalysts. [ABSTRACT FROM AUTHOR]

Published

2024

15. Sulfur Changes the Electrochemical CO2 Reduction Pathway over Cu Electrocatalysts.

Author

Liang, Shuyu, Xiao, Jiewen, Zhang, Tianyu, Zheng, Yue, Wang, Qiang, and Liu, Bin

Subjects

*ELECTROLYTIC reduction, *COPPER, *ELECTROCATALYSTS, *INFRARED absorption, *CHEMICAL reduction, *HYDROGEN evolution reactions

Abstract

Electrochemical CO2 reduction to value‐added chemicals or fuels offers a promising approach to reduce carbon emissions and alleviate energy shortage. Cu‐based electrocatalysts have been widely reported as capable of reducing CO2 to produce a variety of multicarbon products (e.g. ethylene and ethanol). In this work, we develop sulfur‐doped Cu2O electrocatalysts, which instead can electrochemically reduce CO2 to almost exclusively formate. We show that a dynamic equilibrium of S exists at the Cu2O‐electrolyte interface, and S‐doped Cu2O undergoes in situ surface reconstruction to generate active S‐adsorbed metallic Cu sites during the CO2 reduction reaction (CO2RR). Density functional theory (DFT) calculations together with in situ infrared absorption spectroscopy measurements show that the S‐adsorbed metallic Cu surface can not only promote the formation of the *OCHO intermediate but also greatly suppress *H and *COOH adsorption, thus facilitating CO2‐to‐formate conversion during the electrochemical CO2RR. [ABSTRACT FROM AUTHOR]

Published

2023

16. Post‐Nickelation of a Crystalline Trinuclear Copper Organic Framework for Synergistic Photocatalytic Carbon Dioxide Conversion.

Author

Wang, Xinxin, Ding, Xu, Jin, Yucheng, Qi, Dongdong, Wang, Hailong, Han, Yuesheng, Wang, Tianyu, and Jiang, Jianzhuang

Subjects

*CARBON dioxide, *X-ray powder diffraction, *OXIDATION states, *ELECTRONIC structure, *STRUCTURAL frames

Abstract

Rational regulation of electronic structures and functionalities of framework materials still remains challenging. Herein, reaction of 4,4′,4′′‐nitrilo‐tribenzhydrazide with tris(μ2‐4‐carboxaldehyde‐pyrazolato‐N,N′)‐tricopper (Cu3Py3) generates the crystalline copper organic framework USTB‐11(Cu). Post‐modification with divalent nickel ions affords the heterometallic framework USTB‐11(Cu,Ni). Powder X‐ray diffraction and theoretical simulations reveal their two‐dimensional hexagonal structure geometry. A series of advanced spectroscopic techniques disclose the mixed CuI/CuII state nature of Cu3Py3 in USTB‐11(Cu,Ni) with a uniform bistable Cu34+(CuI2CuII) : Cu35+(CuICuII2) (ca. 1 : 3) oxidation state, resulting in a significantly improved formation efficiency of the charge‐separation state. This endows the Ni sites with enhanced activity and USTB‐11(Cu,Ni) with outstanding photocatalytic CO2 to CO performance with a conversion rate of 22 130 μmol g−1 h−1 and selectivity of 98 %. [ABSTRACT FROM AUTHOR]

Published

2023

17. Electronic Perturbation of Copper Single‐Atom CO2 Reduction Catalysts in a Molecular Way.

Author

Zou, Haiyuan, Zhao, Gang, Dai, Hao, Dong, Hongliang, Luo, Wen, Wang, Lei, Lu, Zhouguang, Luo, Yi, Zhang, Guozhen, and Duan, Lele

Subjects

*CATALYSTS, *CATALYTIC activity, *CATALYST structure, *COPPER, *ELECTRONIC structure, *ELECTROCATALYSIS

Abstract

Fine‐tuning electronic structures of single‐atom catalysts (SACs) plays a crucial role in harnessing their catalytic activities, yet challenges remain at a molecular scale in a controlled fashion. By tailoring the structure of graphdiyne (GDY) with electron‐withdrawing/‐donating groups, we show herein the electronic perturbation of Cu single‐atom CO2 reduction catalysts in a molecular way. The elaborately introduced functional groups (−F, −H and −OMe) can regulate the valance state of Cuδ+, which is found to be directly scaled with the selectivity of the electrochemical CO2‐to‐CH4 conversion. An optimum CH4 Faradaic efficiency of 72.3 % was achieved over the Cu SAC on the F‐substituted GDY. In situ spectroscopic studies and theoretical calculations revealed that the positive Cuδ+ centers adjusted by the electron‐withdrawing group decrease the pKa of adsorbed H2O, promoting the hydrogenation of intermediates toward the CH4 production. Our strategy paves the way for precise electronic perturbation of SACs toward efficient electrocatalysis. [ABSTRACT FROM AUTHOR]

Published

2023

18. Improving the Accuracy of Modelling CO2 Electroreduction on Copper Using Many‐Body Perturbation Theory.

Author

Wei, Ziyang and Sautet, Philippe

Subjects

*PERTURBATION theory, *ELECTROLYTIC reduction, *DENSITY functional theory, *COPPER, *SURFACE stability, *CARBON dioxide reduction, *ELECTRON configuration

Abstract

Copper (Cu) remains the most important metal catalyst for the carbon dioxide reduction reaction (CO2RR) into C2 products. Due to limited evidence from in situ experiments, mechanistic studies are often performed in the framework of density functional theory (DFT), using functionals at the generalized gradient approximation (GGA) level, which have fundamental difficulties to correctly describe CO adsorption and surface stability. We employ the adiabatic connection fluctuation dissipation theorem within the random phase approximation (RPA), in combination with the linearized Poisson–Boltzmann equation to describe solvation effects, to investigate the mechanism of CO2RR on the Cu(100) facet. Qualitatively different from the DFT‐GGA results, RPA results propose the formation of *OCCHO as the potential determining step towards C2 products. The results suggest that it is important to use more accurate methods like RPA when modeling reactions involving multiple CO‐related species like CO2RR. [ABSTRACT FROM AUTHOR]

Published

2022

19. In Operando Identification of In Situ Formed Metalloid Zincδ+ Active Sites for Highly Efficient Electrocatalyzed Carbon Dioxide Reduction.

Author

Zhang, Xin Yu, Li, Wen Jing, Chen, Jiacheng, Wu, Xue Feng, Liu, Yuan Wei, Mao, Fangxin, Yuan, Hai Yang, Zhu, Minghui, Dai, Sheng, Wang, Hai Feng, Hu, P., Sun, Chenghua, Liu, Peng Fei, and Yang, Hua Gui

Subjects

*CARBON dioxide reduction, *SEMIMETALS, *GLOBAL optimization, *GREENHOUSE effect, *X-ray absorption near edge structure, *X-ray absorption, *ELECTROLYTIC reduction

Abstract

Electrochemical CO2‐to‐CO conversion provides a possible way to address problems associated with the greenhouse effect; however, developing low‐cost electrocatalysts to mediate high‐efficiency CO2 reduction remains a challenge on account of the limited understanding of the nature of the real active sites. Herein, we reveal the Znδ+ metalloid sites as the real active sites of stable nonstoichiometric ZnOx structure derived from Zn2P2O7 through operando X‐ray absorption fine structure analysis in conjunction with evolutionary‐algorithm‐based global optimization. Furthermore, theoretical and experimental results demonstrated that Znδ+ metalloid active sites could facilitate the activation of CO2 and the hydrogenation of *CO2, thus accelerating the CO2‐to‐CO conversion. Our work establishes a critical fundamental understanding of the origin of the real active center in the zinc‐based electrocatalysts for CO2 reduction reaction. [ABSTRACT FROM AUTHOR]

Published

2022

20. The Crystal Plane is not the Key Factor for CO2‐to‐Methane Electrosynthesis on Reconstructed Cu2O Microparticles.

Author

Deng, Bangwei, Huang, Ming, Li, Kanglu, Zhao, Xiaoli, Geng, Qin, Chen, Si, Xie, Hongtao, Dong, Xing'an, Wang, Hong, and Dong, Fan

Subjects

*GIBBS' free energy, *ELECTROSYNTHESIS, *CRYSTALS, *DENSITY functional theory, *SLOPE stability

Abstract

Cu2O microparticles with controllable crystal planes and relatively high stability have been recognized as a good platform to understand the mechanism of the electrocatalytic CO2 reduction reaction (CO2RR). Herein, we demonstrate that the in situ generated Cu2O/Cu interface plays a key role in determining the selectivity of methane formation, rather than the initial crystal plane of the reconstructed Cu2O microparticles. Experimental results indicate that the methane evolution is dominated on all three different crystal planes with similar Tafel slopes and long‐term stabilities. Density functional theory (DFT) calculations further reveal that *CO is protonated via a similar bridge configuration at the Cu2O/Cu interface, regardless of the initial crystal planes of Cu2O. The Gibbs free energy changes (ΔG) of *CHO on different reconstructed Cu2O planes are close and more negative than that of *OCCOH, indicating the methane formation is more favorable than ethylene on all Cu2O crystal planes. [ABSTRACT FROM AUTHOR]

Published

2022

21. Highly Ethylene‐Selective Electrocatalytic CO2 Reduction Enabled by Isolated Cu−S Motifs in Metal–Organic Framework Based Precatalysts.

Author

Wen, Chun Fang, Zhou, Min, Liu, Peng Fei, Liu, Yuanwei, Wu, Xuefeng, Mao, Fangxin, Dai, Sheng, Xu, Beibei, Wang, Xue Lu, Jiang, Zheng, Hu, P., Yang, Shuang, Wang, Hai Feng, and Yang, Hua Gui

Subjects

*METAL-organic frameworks, *DENSITY functional theory, *X-ray absorption, *CARBON dioxide, *COPPER catalysts

Abstract

Copper‐based materials are efficient electrocatalysts for the conversion of CO2 to C2+ products, and most these materials are reconstructed in situ to regenerate active species. It is a challenge to precisely design precatalysts to obtain active sites for the CO2 reduction reaction (CO2RR). Herein, we develop a strategy based on local sulfur doping of a Cu‐based metal–organic framework precatalyst, in which the stable Cu−S motif is dispersed in the framework of HKUST‐1 (S‐HKUST‐1). The precatalyst exhibits a high ethylene selectivity in an H‐type cell with a maximum faradaic efficiency (FE) of 60.0 %, and delivers a current density of 400 mA cm−2 with an ethylene FE up to 57.2 % in a flow cell. Operando X‐ray absorption results demonstrate that Cuδ+ species stabilized by the Cu−S motif exist in S‐HKUST‐1 during CO2RR. Density functional theory calculations indicate the partially oxidized Cuδ+ at the Cu/CuxSy interface is favorable for coupling of the *CO intermediate due to the modest distance between coupling sites and optimized adsorption energy. [ABSTRACT FROM AUTHOR]

Published

2022

22. Homoleptic Alkynyl‐Protected Ag15 Nanocluster with Atomic Precision: Structural Analysis and Electrocatalytic Performance toward CO2 Reduction.

Author

Qin, Lubing, Sun, Fang, Ma, Xiaoshuang, Ma, Guanyu, Tang, Yun, Wang, Likai, Tang, Qing, Jin, Rongchao, and Tang, Zhenghua

Subjects

*GOLD clusters, *DENSITY functional theory, *CRYSTAL growth, *CRYSTAL structure, *CARBON dioxide

Abstract

We report the fabrication of homoleptic alkynyl‐protected Ag15(C≡C‐tBu)12+ (abbreviated as Ag15) nanocluster and its electrocatalytic properties toward CO2 reduction reaction. Crystal structure analysis reveals that Ag15 possesses a body‐centered‐cubic (BCC) structure with an Ag@Ag8@Ag6 metal core configuration. Interestingly, we found that Ag15 can adsorb CO2 in the air and spontaneously self‐assembled into one‐dimensional linear material during the crystal growth process. Furthermore, Ag15 can convert CO2 into CO with a faradaic efficiency of ca. 95.0 % at −0.6 V and a maximal turnover frequency of 6.37 s−1 at −1.1 V along with excellent long‐term stability. Finally, density functional theory (DFT) calculations disclosed that Ag15(C≡C‐tBu)11+ with one alkynyl ligand stripping off from the intact cluster can expose the uncoordinated Ag atom as the catalytically active site for CO formation. [ABSTRACT FROM AUTHOR]

Published

2021

23. A Supported Pd2 Dual‐Atom Site Catalyst for Efficient Electrochemical CO2 Reduction.

Author

Zhang, Ningqiang, Zhang, Xinxin, Kang, Yikun, Ye, Chenliang, Jin, Rui, Yan, Han, Lin, Rui, Yang, Jiarui, Xu, Qian, Wang, Yu, Zhang, Qinghua, Gu, Lin, Liu, Licheng, Song, Weiyu, Liu, Jian, Wang, Dingsheng, and Li, Yadong

Subjects

*ELECTROLYTIC reduction, *CHARGE exchange, *CATALYSTS, *CATALYTIC activity, *DENSITY functional theory, *ATOMS

Abstract

Dual‐atom site catalysts (DACs) have emerged as a new frontier in heterogeneous catalysis because the synergistic effect between adjacent metal atoms can promote their catalytic activity while maintaining the advantages of single‐atom site catalysts (SACs), like 100 % atomic utilization efficiency and excellent selectivity. Herein, a supported Pd2 DAC was synthesized and used for electrochemical CO2 reduction reaction (CO2RR) for the first time. The as‐obtained Pd2 DAC exhibited superior CO2RR catalytic performance with 98.2 % CO faradic efficiency at −0.85 V vs. RHE, far exceeding that of Pd1 SAC, and coupled with long‐term stability. The density functional theory (DFT) calculations revealed that the intrinsic reason for the superior activity of Pd2 DAC toward CO2RR was the electron transfer between Pd atoms at the dimeric Pd sites. Thus, Pd2 DAC possessed moderate adsorption strength of CO*, which was beneficial for CO production in CO2RR. [ABSTRACT FROM AUTHOR]

Published

2021

24. Residual Chlorine Induced Cationic Active Species on a Porous Copper Electrocatalyst for Highly Stable Electrochemical CO2 Reduction to C2+.

Author

Li, Minhan, Ma, Yuanyuan, Chen, Jun, Lawrence, Robert, Luo, Wei, Sacchi, Marco, Jiang, Wan, and Yang, Jianping

Subjects

*CHLORINE, *ELECTROLYTIC reduction, *STANDARD hydrogen electrode, *ELECTROCATALYSTS, *COPPER, *ELECTROCATALYSIS, *CARBON dioxide

Abstract

Electrochemical carbon dioxide (CO2) reduction reaction (CO2RR) is an attractive approach to deal with the emission of CO2 and to produce valuable fuels and chemicals in a carbon‐neutral way. Many efforts have been devoted to boost the activity and selectivity of high‐value multicarbon products (C2+) on Cu‐based electrocatalysts. However, Cu‐based CO2RR electrocatalysts suffer from poor catalytic stability mainly due to the structural degradation and loss of active species under CO2RR condition. To date, most reported Cu‐based electrocatalysts present stabilities over dozens of hours, which limits the advance of Cu‐based electrocatalysts for CO2RR. Herein, a porous chlorine‐doped Cu electrocatalyst exhibits high C2+ Faradaic efficiency (FE) of 53.8 % at −1.00 V versus reversible hydrogen electrode (VRHE). Importantly, the catalyst exhibited an outstanding catalytic stability in long‐term electrocatalysis over 240 h. Experimental results show that the chlorine‐induced stable cationic Cu0/Cu+ species and the well‐preserved structure with abundant active sites are critical to the high FE of C2+ in the long‐term run of electrochemical CO2 reduction. [ABSTRACT FROM AUTHOR]

Published

2021

25. Residual Chlorine Induced Cationic Active Species on a Porous Copper Electrocatalyst for Highly Stable Electrochemical CO2 Reduction to C2+.

Author

Li, Minhan, Ma, Yuanyuan, Chen, Jun, Lawrence, Robert, Luo, Wei, Sacchi, Marco, Jiang, Wan, and Yang, Jianping

Subjects

CHLORINE, ELECTROLYTIC reduction, STANDARD hydrogen electrode, ELECTROCATALYSTS, COPPER, ELECTROCATALYSIS, CARBON dioxide

Abstract

Electrochemical carbon dioxide (CO2) reduction reaction (CO2RR) is an attractive approach to deal with the emission of CO2 and to produce valuable fuels and chemicals in a carbon‐neutral way. Many efforts have been devoted to boost the activity and selectivity of high‐value multicarbon products (C2+) on Cu‐based electrocatalysts. However, Cu‐based CO2RR electrocatalysts suffer from poor catalytic stability mainly due to the structural degradation and loss of active species under CO2RR condition. To date, most reported Cu‐based electrocatalysts present stabilities over dozens of hours, which limits the advance of Cu‐based electrocatalysts for CO2RR. Herein, a porous chlorine‐doped Cu electrocatalyst exhibits high C2+ Faradaic efficiency (FE) of 53.8 % at −1.00 V versus reversible hydrogen electrode (VRHE). Importantly, the catalyst exhibited an outstanding catalytic stability in long‐term electrocatalysis over 240 h. Experimental results show that the chlorine‐induced stable cationic Cu0/Cu+ species and the well‐preserved structure with abundant active sites are critical to the high FE of C2+ in the long‐term run of electrochemical CO2 reduction. [ABSTRACT FROM AUTHOR]

Published

2021

26. Hierarchical Metal–Polymer Hybrids for Enhanced CO2 Electroreduction.

Author

Jia, Shuaiqiang, Zhu, Qinggong, Chu, Mengen, Han, Shitao, Feng, Ruting, Zhai, Jianxin, Xia, Wei, He, Mingyuan, Wu, Haihong, and Han, Buxing

Subjects

*ELECTROLYTIC reduction, *ELECTROSYNTHESIS, *MATERIALS science, *ELECTROCATALYSTS, *ELECTROPOLYMERIZATION, *ELECTRODES, *CARBON dioxide

Abstract

The design of catalysts with high activity, selectivity, and stability is key to the electroreduction of CO2. Herein, we report the synthesis of 3D hierarchical metal/polymer–carbon paper (M/polymer‐CP) electrodes by in situ electrosynthesis. The 3D polymer layer on CP (polymer‐CP) was first prepared by in situ electropolymerization, then a 3D metal layer was decorated on the polymer‐CP to produce the M/polymer‐CP electrode. Electrodes with different metals (e.g. Cu, Pd, Zn, Sn) and various polymers could be prepared by this method. The electrodes could efficiently reduce CO2 to desired products, such as C2H4, CO, and HCOOH, depending on the metal used. For example, C2H4 could be formed with a Faradaic efficiency of 59.4 % and a current density of 30.2 mA cm−2 by using a very stable Cu/PANI‐CP electrode in an H‐type cell. Control experiments and theoretical calculations showed that the 3D hierarchical structure of the metals and in situ formation of the electrodes are critical for the excellent performance. [ABSTRACT FROM AUTHOR]

Published

2021

27. Silver Single‐Atom Catalyst for Efficient Electrochemical CO2 Reduction Synthesized from Thermal Transformation and Surface Reconstruction.

Author

Zhang, Ningqiang, Zhang, Xinxin, Tao, Lei, Jiang, Peng, Ye, Chenliang, Lin, Rui, Huang, Zhiwei, Li, Ang, Pang, Dawei, Yan, Han, Wang, Yu, Xu, Peng, An, Sufeng, Zhang, Qinghua, Liu, Licheng, Du, Shixuan, Han, Xiaodong, Wang, Dingsheng, and Li, Yadong

Subjects

*SILVER catalysts, *SURFACE reconstruction, *ELECTROLYTIC reduction, *FERMI level, *SURFACE preparation, *SILVER alloys

Abstract

We report an Ag1 single‐atom catalyst (Ag1/MnO2), which was synthesized from thermal transformation of Ag nanoparticles (NPs) and surface reconstruction of MnO2. The evolution process of Ag NPs to single atoms is firstly revealed by various techniques, including in situ ETEM, in situ XRD and DFT calculations. The temperature‐induced surface reconstruction process from the MnO2 (211) to (310) lattice plane is critical to firmly confine the existing surface of Ag single atoms; that is, the thermal treatment and surface reconstruction of MnO2 is the driving force for the formation of single Ag atoms. The as‐obtained Ag1/MnO2 achieved 95.7 % Faradic efficiency at −0.85 V vs. RHE, and coupled with long‐term stability for electrochemical CO2 reduction reaction (CO2RR). DFT calculations indicated single Ag sites possessed high electronic density close to Fermi Level and could act exclusively as the active sites in the CO2RR. As a result, the Ag1/MnO2 catalyst demonstrated remarkable performance for the CO2RR, far surpassing the conventional Ag nanosized catalyst (AgNP/MnO2) and other reported Ag‐based catalysts. [ABSTRACT FROM AUTHOR]

Published

2021

28. Polyoxometalate‐Based Compounds for Photo‐ and Electrocatalytic Applications.

Author

Li, Ning, Liu, Jiang, Dong, Bao‐Xia, and Lan, Ya‐Qian

Subjects

*ELECTROCATALYSIS, *HYDROGEN evolution reactions, *OXYGEN evolution reactions, *CARBON dioxide, *ENERGY shortages, *ACTIVATION energy

Abstract

Photo/electrocatalysis of water (H2O) splitting and CO2 reduction reactions is a promising strategy to alleviate the energy crisis and excessive CO2 emissions. For the hydrogen evolution reaction (HER), oxygen evolution reaction (OER), and CO2 reduction reaction (CO2RR) involved, the development of effective photo/electrocatalysts is critical to reduce the activation energy and accelerate the sluggish dynamics. Polyoxometalate (POM)‐based compounds with tunable compositions and diverse structures are emerging as unique photo/electrocatalysts for these reactions as they offer unparalleled advantages such as outstanding solution and redox stability, quasi‐semiconductor behaviour, etc. This Minireview provides a basic introduction related to photo/electrocatalytic HER, OER and CO2RR, followed by the classification of pristine POM‐based compounds toward different catalytic reactions. Recent breakthroughs in engineering POM‐based compounds as efficient photo/electrocatalysts are highlighted. Finally, the advantages, challenges, strategies and outlooks of POM‐based compounds on improving photo/electrocatalytic performance are discussed. [ABSTRACT FROM AUTHOR]

Published

2020

29. Electrochemically Driven Cation Exchange Enables the Rational Design of Active CO2 Reduction Electrocatalysts.

Author

He, Wenhui, Liberman, Itamar, Rozenberg, Illya, Ifraemov, Raya, and Hod, Idan

Subjects

*ELECTROCATALYSTS, *METAL sulfides, *METALLIC oxides, *CRYSTAL grain boundaries, *CARBON dioxide reduction, *CATIONS, *ELECTROLYTIC reduction, *CATALYSTS

Abstract

Metal oxides or sulfides are considered to be one of the most promising CO2 reduction reaction (CO2RR) precatalysts, owing to their electrochemical conversion in situ into highly active electrocatalytic species. However, further improvement of the performance requires new tools to gain fine control over the composition of the active species and its structural features [e.g. grain boundaries (GBs) and undercoordinated sites (USs)], directly from a predesigned template material. Herein, we describe a novel electrochemically driven cation exchange (ED‐CE) method that enables the conversion of a predesigned CoS2 template into a CO2RR catalyst, Cu2S. By means of ED‐CE, the final Cu2S catalyst inherits the original 3 D morphology of CoS2, and preserves its high density of GBs. Additionally, the catalyst's phase structure, composition, and density of USs were precisely tuned, thus enabling rational design of active CO2RR sites. The obtained Cu2S catalyst achieved a CO2‐to‐formate Faradaic efficiency of over 87 % and a record high activity (among reported Cu‐based catalysts). Hence, this study opens the way for utilization of ED‐CE reactions to design advanced electrocatalysts. [ABSTRACT FROM AUTHOR]

Published

2020

30. Highly Selective Electrochemical Reduction of CO2 to Alcohols on an FeP Nanoarray.

Author

Ji, Lei, Li, Lei, Ji, Xuqiang, Zhang, Ya, Mou, Shiyong, Wu, Tongwei, Liu, Qian, Li, Baihai, Zhu, Xiaojuan, Luo, Yonglan, Shi, Xifeng, Asiri, Abdullah M., and Sun, Xuping

Subjects

*ELECTROLYTIC reduction, *STANDARD hydrogen electrode, *DENSITY functional theory, *ALCOHOL, *SUSTAINABILITY

Abstract

Electrochemical reduction of CO2 into various chemicals and fuels provides an attractive pathway for environmental and energy sustainability. It is now shown that a FeP nanoarray on Ti mesh (FeP NA/TM) acts as an efficient 3D catalyst electrode for the CO2 reduction reaction to convert CO2 into alcohols with high selectivity. In 0.5 m KHCO3, such FeP NA/TM is capable of achieving a high Faradaic efficiency (FECH3OH) up to 80.2 %, with a total FECH3OH+C2H5OH of 94.3 % at −0.20 V vs. reversible hydrogen electrode. Density functional theory calculations reveal that the FeP(211) surface significantly promotes the adsorption and reduction of CO2 toward CH3OH owing to the synergistic effect of two adjacent Fe atoms, and the potential‐determining step is the hydrogenation process of *CO. [ABSTRACT FROM AUTHOR]

Published

2020

31. Electrochemical Reduction of Carbon Dioxide to Methanol on Hierarchical Pd/SnO2 Nanosheets with Abundant Pd–O–Sn Interfaces.

Author

Zhang, Wuyong, Qin, Qing, Dai, Lei, Qin, Ruixuan, Zhao, Xiaojing, Chen, Xumao, Ou, Daohui, Chen, Jie, Chuong, Tracy T., Wu, Binghui, and Zheng, Nanfeng

Subjects

*CARBON dioxide, *ELECTROLYTIC reduction, *METHANOL, *PALLADIUM, *STANNIC oxide

Abstract

Abstract: Electrochemical conversion of CO2 into fuels using electricity generated from renewable sources helps to create an artificial carbon cycle. However, the low efficiency and poor stability hinder the practical use of most conventional electrocatalysts. In this work, a 2D hierarchical Pd/SnO2 structure, ultrathin Pd nanosheets partially capped by SnO2 nanoparticles, is designed to enable multi‐electron transfer for selective electroreduction of CO2 into CH3OH. Such a structure design not only enhances the adsorption of CO2 on SnO2, but also weakens the binding strength of CO on Pd due to the as‐built Pd–O–Sn interfaces, which is demonstrated to be critical to improve the electrocatalytic selectivity and stability of Pd catalysts. This work provides a new strategy to improve electrochemical performance of metal‐based catalysts by creating metal oxide interfaces for selective electroreduction of CO2. [ABSTRACT FROM AUTHOR]

Published

2018