Single-atom catalysts(SACs)with M-N_(4)structure have drawn significant attention due to the facile preparation,maximum atom efficiency,unique electronic properties,uniform active sites,and excellent activity.Such cat...Single-atom catalysts(SACs)with M-N_(4)structure have drawn significant attention due to the facile preparation,maximum atom efficiency,unique electronic properties,uniform active sites,and excellent activity.Such catalysts integrated the merits of traditional homogeneous and heterogeneous catalysts effectively solve the cost,activity,and reuse problems.More importantly,the M-N_(4)structure is flexible and other species like atoms,groups,and particles can be added to precisely control the local environment of M-N_(4)to further improve the catalytic performance.Although unprecedented progress has been made,it remains difficulties in the rational design and controllable synthesis of a suitable SAC for a certain application.This review introduces the progress of M-N_(4)catalysts and summarizes the strategies to modulate the M-N_(4)structure,including changing the coordination number,tailoring the coordination structure,coordinating with groups,creating dual-atom catalysts(DACs),and coexisting of SAC with DAC and cluster.Special emphasis is placed on the preparation,structure characterization,and reaction mechanism of M-N_(4)-derived catalysts.Finally,the current challenges of these catalysts are also discussed to provide guidelines for the future design of efficient catalysts.展开更多
Electrochemical CO_(2)reduction reaction(CO_(2)RR)has attracted considerable attention in the recent decade for its critical role in the storage of renewable energy and fulfilling of the carbon cycle,and catalysts wit...Electrochemical CO_(2)reduction reaction(CO_(2)RR)has attracted considerable attention in the recent decade for its critical role in the storage of renewable energy and fulfilling of the carbon cycle,and catalysts with varying morphology and modification strategies have been studied to improve the CO_(2)RR activity and selectivity.However,most of the achievements are focused on preliminary reduction products such as CO and HCOOH.Development and research on electrochemical CO reduction reaction(CORR)are considered to be more promising to achieve multicarbon products and a better platform to understand the mechanism of C-C formation.In this review,we introduce the current achievements of CO_(2)RR and emphasize the potential of CORR.We provide a summary of how electrolysis environment,electrode substrates,and cell design affect the performance of CORR catalysts in order to offer a guideline of standard operating conditions for CORR research.The composition-structure-activity relationships for CORR catalysts studied in H-cells and gas-phase flow cells are separately analyzed to give a comprehensive understanding of the development of catalyst design.Finally,the reaction mechanism,latest progress,major challenges and potential opportunities of CORR are also analyzed to provide a critical overview for further performance improvement of CORR.展开更多
Single-atom catalysts(SACs)have shown unexpected catalytic activity due to their unique electronic structure and coordination environment.Nonetheless,the synthesis of an atomically precise low-coordination single-atom...Single-atom catalysts(SACs)have shown unexpected catalytic activity due to their unique electronic structure and coordination environment.Nonetheless,the synthesis of an atomically precise low-coordination single-atom catalyst remains a grand challenge.Herein,we report a coordinately unsaturated Ni-N_(3)single-atom electrocatalyst using a metal-organic framework(MOF)derived N-C support with abundant exposed N for excellent electrochemical CO_(2)reduction.The obtained Ni-N_(3)/NC active site exhibited highly efficient CO_(2)-to-CO conversion with a Faradaic efficiency of 94.6%at the current density of 100 mA/cm^(2).In situ X-ray absorption spectroscopy(XAS)measurement suggested that the Ni atomic center with unsaturated coordination had the lower initial chemical state and higher charge transfer ability.In situ Fourier transform infrared(FT-IR)and theoretical calculation results revealed that the unsaturated catalytically active center could facilitate activation of CO_(2)and thus heighten CO_(2)electroreduction activity.These findings provided insights into the rational design of definitive coordination structure of SACs for boosting activity and selectivity.展开更多
合理的设计策略以提高贵金属电催化剂在析氢反应(HER)中的利用率,对于简化HER的工艺流程,促进未来能源循环经济的发展至关重要.本文在约2.4 nm的Ru纳米颗粒上设计了大量的缺陷,使其在苛刻的酸性和碱性电解质中具有超高质量比反应活性....合理的设计策略以提高贵金属电催化剂在析氢反应(HER)中的利用率,对于简化HER的工艺流程,促进未来能源循环经济的发展至关重要.本文在约2.4 nm的Ru纳米颗粒上设计了大量的缺陷,使其在苛刻的酸性和碱性电解质中具有超高质量比反应活性.在过电势为100 m V时,所制备的缺陷富集型Ru基电催化剂DR-Ru表现出超高的HER翻转频率(碱性:16.4 s^(-1);酸性:20.6 s^(-1))和超低的过电势(碱性:η10=28.2 m V;酸性:η10=25.1 mV),明显优于其他Ru基电催化剂.此外,低配位的Ru活性位和表面部分晶格氧削弱了DR-Ru的Ru–H结合能,促进了酸性HER进行;同时有利于H2O分子分解,缓解了碱性HER过程中水分子的解离迟滞,导致其具有与酸性HER相当的高质量比活性.展开更多
基金This work was supported by the National Natural Science Foundation of China(Nos.22002191,12105287,22179125,22002147,and 12025505)the Natural Science Foundation of Guangdong Province(Nos.2022A1515010928 and 2022A1515012661)+3 种基金Shenzhen Science and Technology Program(No.JCYJ20220530150200002)Guangdong Basic and Applied Basic Research Foundation(No.2022A1515110956)the Youth Innovation Promotion Association CAS(No.2022458)Fundamental Research Funds for the Central Universities(No.KY2310000020).
文摘Single-atom catalysts(SACs)with M-N_(4)structure have drawn significant attention due to the facile preparation,maximum atom efficiency,unique electronic properties,uniform active sites,and excellent activity.Such catalysts integrated the merits of traditional homogeneous and heterogeneous catalysts effectively solve the cost,activity,and reuse problems.More importantly,the M-N_(4)structure is flexible and other species like atoms,groups,and particles can be added to precisely control the local environment of M-N_(4)to further improve the catalytic performance.Although unprecedented progress has been made,it remains difficulties in the rational design and controllable synthesis of a suitable SAC for a certain application.This review introduces the progress of M-N_(4)catalysts and summarizes the strategies to modulate the M-N_(4)structure,including changing the coordination number,tailoring the coordination structure,coordinating with groups,creating dual-atom catalysts(DACs),and coexisting of SAC with DAC and cluster.Special emphasis is placed on the preparation,structure characterization,and reaction mechanism of M-N_(4)-derived catalysts.Finally,the current challenges of these catalysts are also discussed to provide guidelines for the future design of efficient catalysts.
基金Changli Li acknowledges financial funding from National Natural Science Foundation of China(No.22002191)Qinghua Liu acknowledges funding from the National Natural Science Foundation of China(U1932212 and 11875257).
文摘Electrochemical CO_(2)reduction reaction(CO_(2)RR)has attracted considerable attention in the recent decade for its critical role in the storage of renewable energy and fulfilling of the carbon cycle,and catalysts with varying morphology and modification strategies have been studied to improve the CO_(2)RR activity and selectivity.However,most of the achievements are focused on preliminary reduction products such as CO and HCOOH.Development and research on electrochemical CO reduction reaction(CORR)are considered to be more promising to achieve multicarbon products and a better platform to understand the mechanism of C-C formation.In this review,we introduce the current achievements of CO_(2)RR and emphasize the potential of CORR.We provide a summary of how electrolysis environment,electrode substrates,and cell design affect the performance of CORR catalysts in order to offer a guideline of standard operating conditions for CORR research.The composition-structure-activity relationships for CORR catalysts studied in H-cells and gas-phase flow cells are separately analyzed to give a comprehensive understanding of the development of catalyst design.Finally,the reaction mechanism,latest progress,major challenges and potential opportunities of CORR are also analyzed to provide a critical overview for further performance improvement of CORR.
基金supported by Guangdong Basic and Applied Basic Research Foundation(No.2022A1515011828)Natural Science Foundation of Guangdong Province(No.2022A1515012661)+4 种基金the National Key R&D Program of China(Nos.2021YFA1600800 and 2020YFA0710203)the National Natural Science Foundation of China(Nos.12025505,22179125,22002147,22106126,and 12205304)the Strategic Priority Research Program of the Chinese Academy of Sciences(No.XDB0450200)the Youth Innovation Promotion Association CAS(Nos.2015366 and 2022458)the Collaborative Innovation Program of Hefei Science Center,CAS(No.2021HSC-CIP006).
文摘Single-atom catalysts(SACs)have shown unexpected catalytic activity due to their unique electronic structure and coordination environment.Nonetheless,the synthesis of an atomically precise low-coordination single-atom catalyst remains a grand challenge.Herein,we report a coordinately unsaturated Ni-N_(3)single-atom electrocatalyst using a metal-organic framework(MOF)derived N-C support with abundant exposed N for excellent electrochemical CO_(2)reduction.The obtained Ni-N_(3)/NC active site exhibited highly efficient CO_(2)-to-CO conversion with a Faradaic efficiency of 94.6%at the current density of 100 mA/cm^(2).In situ X-ray absorption spectroscopy(XAS)measurement suggested that the Ni atomic center with unsaturated coordination had the lower initial chemical state and higher charge transfer ability.In situ Fourier transform infrared(FT-IR)and theoretical calculation results revealed that the unsaturated catalytically active center could facilitate activation of CO_(2)and thus heighten CO_(2)electroreduction activity.These findings provided insights into the rational design of definitive coordination structure of SACs for boosting activity and selectivity.
基金supported by the National Natural Science Foundation of China (U1932212, 11875257, and U1932109)the Fundamental Research Funds for the Central Universities (WK2310000070)
文摘合理的设计策略以提高贵金属电催化剂在析氢反应(HER)中的利用率,对于简化HER的工艺流程,促进未来能源循环经济的发展至关重要.本文在约2.4 nm的Ru纳米颗粒上设计了大量的缺陷,使其在苛刻的酸性和碱性电解质中具有超高质量比反应活性.在过电势为100 m V时,所制备的缺陷富集型Ru基电催化剂DR-Ru表现出超高的HER翻转频率(碱性:16.4 s^(-1);酸性:20.6 s^(-1))和超低的过电势(碱性:η10=28.2 m V;酸性:η10=25.1 mV),明显优于其他Ru基电催化剂.此外,低配位的Ru活性位和表面部分晶格氧削弱了DR-Ru的Ru–H结合能,促进了酸性HER进行;同时有利于H2O分子分解,缓解了碱性HER过程中水分子的解离迟滞,导致其具有与酸性HER相当的高质量比活性.