Water electrolysis for green hydrogen production is important for the global carbon neutrality.The industrialization of this technology requires efficient and durable electrocatalysts under high-current-density(HCD)op...Water electrolysis for green hydrogen production is important for the global carbon neutrality.The industrialization of this technology requires efficient and durable electrocatalysts under high-current-density(HCD)operations.However,the insufficient mass and charge transfer at the various interfaces lead to unsatisfactory HCD activity and durability.Interface engineering is important for designing efficient HCD electrocatalysts.In this perspective,we analyze the processes taking place at three interfaces including the catalyst-substrate,catalyst-electrolyte,and catalyst-gas interfaces,and reveal the correlations between interface interactions and the challenges for HCD electrolysis.We then highlight the development of HCD electrocatalysts that focus on interface engineering using the example of transition metal dichalcogenide based catalysts,which have attracted widespread interests in recent years.Finally,we give an outlook on the development of interface engineering for the industrialization of water electrolysis technology.展开更多
As an important energy carrier in terms of carbon neutrality,green hydrogen produced by water electrolysis using renewable electricity has attracted worldwide attention.The polymer electrolyte water electrolyzer(PEWE)...As an important energy carrier in terms of carbon neutrality,green hydrogen produced by water electrolysis using renewable electricity has attracted worldwide attention.The polymer electrolyte water electrolyzer(PEWE)has the potential to be a mainstay in the green hydrogen market in the future because of its superior performance.However,the development of PEWE is constrained by the slow progress of the membrane electrode assembly(MEA),which is an essential component of PEWE and largely determines the cost and performance of the system.Therefore,the MEA must be optimized from the aspects of reducing cost and improving performance to promote the development of PEWEs.In this review,we first discuss the recent progress of the materials and design strategies of MEA,including the cost,activity,and stability of catalysts,distribution and thickness of ionomers,and ion transport efficiency of ion exchange membranes(IEMs).Then,the effects of all components and interlayer interfaces on the ions,electrons,and mass transfer in MEA and,consequently,the performance of PEWE are analyzed.Finally,we propose perspectives on developing MEA by optimizing the catalyst activity and stability of IEM,interface contact between adjacent components,and evaluation methods of performance.展开更多
As one of the best electrocatalysts for the hydrogen evolution reaction,platinum catalysts are a benchmark for the performance evaluation of new catalysts.However,platinum catalysts reported in the literature show div...As one of the best electrocatalysts for the hydrogen evolution reaction,platinum catalysts are a benchmark for the performance evaluation of new catalysts.However,platinum catalysts reported in the literature show diverse electrocatalytic performances,resulting in the lack of a common reference standard.In this study,we investigated several factors that affect the performance of platinum catalysts by performing experimental measurements and data processing.These factors included the solution resistance,electrolyte temperature,loading quantity,catalyst microstructure,and normalization method of the current density.Finally,we recommended criteria for the performance evaluation of electrocatalysts.展开更多
文摘Water electrolysis for green hydrogen production is important for the global carbon neutrality.The industrialization of this technology requires efficient and durable electrocatalysts under high-current-density(HCD)operations.However,the insufficient mass and charge transfer at the various interfaces lead to unsatisfactory HCD activity and durability.Interface engineering is important for designing efficient HCD electrocatalysts.In this perspective,we analyze the processes taking place at three interfaces including the catalyst-substrate,catalyst-electrolyte,and catalyst-gas interfaces,and reveal the correlations between interface interactions and the challenges for HCD electrolysis.We then highlight the development of HCD electrocatalysts that focus on interface engineering using the example of transition metal dichalcogenide based catalysts,which have attracted widespread interests in recent years.Finally,we give an outlook on the development of interface engineering for the industrialization of water electrolysis technology.
基金the National Natural Science Foundation of China(52188101)the National Science Fund for Distinguished Young Scholars(52125309)+2 种基金Guangdong Basic and Applied Basic Research Foundation(2021A1515110829)Guangdong Innovative and Entrepreneurial Research Team Program(2017ZT07C341)Shenzhen Basic Research Project(JCYJ20200109144620815).
文摘As an important energy carrier in terms of carbon neutrality,green hydrogen produced by water electrolysis using renewable electricity has attracted worldwide attention.The polymer electrolyte water electrolyzer(PEWE)has the potential to be a mainstay in the green hydrogen market in the future because of its superior performance.However,the development of PEWE is constrained by the slow progress of the membrane electrode assembly(MEA),which is an essential component of PEWE and largely determines the cost and performance of the system.Therefore,the MEA must be optimized from the aspects of reducing cost and improving performance to promote the development of PEWEs.In this review,we first discuss the recent progress of the materials and design strategies of MEA,including the cost,activity,and stability of catalysts,distribution and thickness of ionomers,and ion transport efficiency of ion exchange membranes(IEMs).Then,the effects of all components and interlayer interfaces on the ions,electrons,and mass transfer in MEA and,consequently,the performance of PEWE are analyzed.Finally,we propose perspectives on developing MEA by optimizing the catalyst activity and stability of IEM,interface contact between adjacent components,and evaluation methods of performance.
基金the Key Laboratory of Two-Dimensional Materials(Hunan Province),Hunan University(KF20200002)the National Science Fund for Distinguished Young Scholars(52125309)+1 种基金the Guangdong Innovative and Entrepreneurial Research Team Program(2017ZT07C341)the Shenzhen Basic Research Project(JCYJ20200109144620815).
文摘As one of the best electrocatalysts for the hydrogen evolution reaction,platinum catalysts are a benchmark for the performance evaluation of new catalysts.However,platinum catalysts reported in the literature show diverse electrocatalytic performances,resulting in the lack of a common reference standard.In this study,we investigated several factors that affect the performance of platinum catalysts by performing experimental measurements and data processing.These factors included the solution resistance,electrolyte temperature,loading quantity,catalyst microstructure,and normalization method of the current density.Finally,we recommended criteria for the performance evaluation of electrocatalysts.
