Two-dimensional carbides,nitrides,and carbonitrides(MXenes)play important roles in promoting the development of sustainable energy because they have abundant reactive sites on their surfaces.An increasing number of MX...Two-dimensional carbides,nitrides,and carbonitrides(MXenes)play important roles in promoting the development of sustainable energy because they have abundant reactive sites on their surfaces.An increasing number of MXenes with diverse elements and composites have been predicted and synthesized for electrocatalysis applications since the first report of a Ti-Mo-based MXene for the hydrogen evolution reaction(HER).Herein,we summarize the progress of MXene-based electrocatalysts for the HER,the oxygen evolution reaction,and the oxygen reduction reaction,including regulated pristine MXenes and modified hybrid MXenes,from both theoretical and experimental perspectives.A brief overview on MXene synthesis is presented first,accompanied by a discussion on the relationship between electrocatalytic properties and M,X,T,vacancies,and morphologies.After reviewing strategies in terms of atom substitution,functional modification,defect engineering,and morphology control,we emphasize the construction of heterojunctions between MXenes and other nanostructures,such as metal nanoparticles,oxides,hydroxides,sulfides,and phosphides.We finally discuss prospects for the future development of MXene-based electrocatalysts.展开更多
Cation substitution in spinel cobaltites(e.g.,ACo2O4,in which A=Mn,Fe,Co,Ni,Cu,or Zn)is a promising strategy to precisely modulate their electronic structure/properties and thus improve the corresponding electrochemic...Cation substitution in spinel cobaltites(e.g.,ACo2O4,in which A=Mn,Fe,Co,Ni,Cu,or Zn)is a promising strategy to precisely modulate their electronic structure/properties and thus improve the corresponding electrochemical performance for water splitting.However,the fundamental principles and mechanisms are not fully understood.This research aims to systematically investigate the effects of cation substitution in spinel cobaltites derived from mixed-metal-organic frameworks on the oxygen evolution reaction(OER).Among the obtained ACo2O4 catalysts,FeCo2O4 showed excellent OER performance with a current density of 10 mA·cm^-2 at an overpotential of 164 mV in alkaline media.Both theoretical calculations and experimental results demonstrate that the Fe substitution in the crystal lattice of ACo2O4 can significantly accelerate charge transfer,thereby achieving enhanced electrochemical properties.The crystal field of spinel ACo2O4,which determines the valence states of cations A,is identified as the key factor to dictate the OER performance of these spinel cobaltites.展开更多
Nano‐catalysis plays a vital role in the chemical transformations and significantly impacts the booming modern chemical industry.The rapid technological enhancements have resulted in serious energy and environmental ...Nano‐catalysis plays a vital role in the chemical transformations and significantly impacts the booming modern chemical industry.The rapid technological enhancements have resulted in serious energy and environmental issues,which are currently spurring the exploration of the novel nano‐catalysts in diverse fields.In order to develop the efficient nano‐catalysts,it is essential to understand their fundamental physicochemical properties,including the coordination structures of the active centers and substrate‐adsorbate interactions.Subsequently,the nano‐catalyst design with precise manipulation at the atomic level can be attained.In this account,we have summarized our extensive investigation of the factors impacting nano‐catalysis,along with the synthetic strategies developed to prepare the nano‐catalysts for applications in electrocatalysis,photocatalysis and thermocatalysis.Finally,a brief conclusion and future research directions on nano‐catalysis have also been presented.展开更多
文摘Two-dimensional carbides,nitrides,and carbonitrides(MXenes)play important roles in promoting the development of sustainable energy because they have abundant reactive sites on their surfaces.An increasing number of MXenes with diverse elements and composites have been predicted and synthesized for electrocatalysis applications since the first report of a Ti-Mo-based MXene for the hydrogen evolution reaction(HER).Herein,we summarize the progress of MXene-based electrocatalysts for the HER,the oxygen evolution reaction,and the oxygen reduction reaction,including regulated pristine MXenes and modified hybrid MXenes,from both theoretical and experimental perspectives.A brief overview on MXene synthesis is presented first,accompanied by a discussion on the relationship between electrocatalytic properties and M,X,T,vacancies,and morphologies.After reviewing strategies in terms of atom substitution,functional modification,defect engineering,and morphology control,we emphasize the construction of heterojunctions between MXenes and other nanostructures,such as metal nanoparticles,oxides,hydroxides,sulfides,and phosphides.We finally discuss prospects for the future development of MXene-based electrocatalysts.
文摘Cation substitution in spinel cobaltites(e.g.,ACo2O4,in which A=Mn,Fe,Co,Ni,Cu,or Zn)is a promising strategy to precisely modulate their electronic structure/properties and thus improve the corresponding electrochemical performance for water splitting.However,the fundamental principles and mechanisms are not fully understood.This research aims to systematically investigate the effects of cation substitution in spinel cobaltites derived from mixed-metal-organic frameworks on the oxygen evolution reaction(OER).Among the obtained ACo2O4 catalysts,FeCo2O4 showed excellent OER performance with a current density of 10 mA·cm^-2 at an overpotential of 164 mV in alkaline media.Both theoretical calculations and experimental results demonstrate that the Fe substitution in the crystal lattice of ACo2O4 can significantly accelerate charge transfer,thereby achieving enhanced electrochemical properties.The crystal field of spinel ACo2O4,which determines the valence states of cations A,is identified as the key factor to dictate the OER performance of these spinel cobaltites.
文摘Nano‐catalysis plays a vital role in the chemical transformations and significantly impacts the booming modern chemical industry.The rapid technological enhancements have resulted in serious energy and environmental issues,which are currently spurring the exploration of the novel nano‐catalysts in diverse fields.In order to develop the efficient nano‐catalysts,it is essential to understand their fundamental physicochemical properties,including the coordination structures of the active centers and substrate‐adsorbate interactions.Subsequently,the nano‐catalyst design with precise manipulation at the atomic level can be attained.In this account,we have summarized our extensive investigation of the factors impacting nano‐catalysis,along with the synthetic strategies developed to prepare the nano‐catalysts for applications in electrocatalysis,photocatalysis and thermocatalysis.Finally,a brief conclusion and future research directions on nano‐catalysis have also been presented.
