Electrocatalytic CO_(2) reduction reaction(ECO_(2)RR)converts CO_(2) to high-value chemical products and promotes the carbon cycle.Sulfur(S)-modified copper(Cu)and bismuth(Bi)-based catalysts have been recognized as p...Electrocatalytic CO_(2) reduction reaction(ECO_(2)RR)converts CO_(2) to high-value chemical products and promotes the carbon cycle.Sulfur(S)-modified copper(Cu)and bismuth(Bi)-based catalysts have been recognized as promising catalysts for ECO_(2)RR.Both of them are highly active for selective formate generation,however,their poor stability and severe competing hydrogen evolution reaction(HER)remain challenging.Herein,S-doped Cu coated with Bi(Bi/Cu-S)is developed to improve ECO_(2)RR selectivity to formate.Bi/Cu-S/brass mesh(BM)electrode material for ECO_(2)RR was prepared by electrodepositing Bi on the surface of Cu-S/BM nanowires obtained from CuS/BM after the electroreduction.The Faradaic efficiency(FE)of the formate reaches the maximum of 94.3%at-0.9 V vs.reversible hydrogen electrode(RHE)with a partial current density as high as-50.7 mA·cm^(-2) and a yield of 30.7 mmol·h^(-1)·cm^(-2) under 0.5 M KHCO_(3) electrolyte.Meanwhile,the FE of formate is higher than 90%in the voltage range of-0.8 to-1.0 V vs.RHE.It also shows good stability at-0.9 V vs.RHE with the FE of formate remaining above 93%after a 10 h reaction.Density functional theory(DFT)calculations demonstrate that the Bi/Cu-S structure promotes the adsorption of CO_(2) and effectively inhibits HER by enhancing the adsorption of^(*)H to a great extent,improving the selective conversion of CO_(2) to formate.This work deepens the understanding of the mechanism of Cu-Bi-based catalysts and S-modified Cu-based catalysts in selective ECO_(2)RR to formate,and also provides a new strategy for catalyst design.展开更多
To produce a three-dimensional micro/nanocarbon structure,a manufacturing design technique for sub-10 nm carbon fiber arrays on three-dimensional carbon micropillars has been developed;the method involves initiating e...To produce a three-dimensional micro/nanocarbon structure,a manufacturing design technique for sub-10 nm carbon fiber arrays on three-dimensional carbon micropillars has been developed;the method involves initiating electrostatic jetting,forming submicron-to-nanoscale PAN-based fibers,and maximizing the shrinkage from polyacrylonitrile(PAN)-based fibers to carbon fibers.Nanoforming and nanodepositing methods for polyacrylonitrilebased jet fibers as precursors of carbon fibers are proposed for the processing design of electrostatic jet initiation and for the forming design of submicron-to-nanoscale PAN-based fibers by establishing and analyzing mathematical models that include the diameter and tensile stress values of jet fibers and the electric field intensity values on the surfaces of carbon micropillars.In accordance with these methods,an array of jet fibers with diameters of~80 nm is experimentally formed based on the thinning of the electrospinning fluid on top of a dispensing needle,the poking of drum into an electrospinning droplet,and the controlling of the needle–drum distance.When converting thin PANbased jet fibers to carbon fibers,a pyrolysis method consisting of the suspension of jet nanofibers between carbon micropillars,the bond between the fibers and the surface of the carbon micropillar,and the control of micropillar spacing,stabilization temperature,and carbonation rate is presented to maximize the shrinkage from PAN-based fibers to carbon fibers and to form sub-10 nm carbon fiber arrays between three-dimensional carbon micropillars.The manufacturing design of a three-dimensional micro/nanocarbon structure can produce thin PAN-based jet nanofibers and nanofiber arrays aligned on micropillar surfaces,obtain shrinkage levels reaching 96%and incorporate sub-10 nm carbon fibers into three-dimensional carbon micropillars;these actions provide new research opportunities for correlated three-dimensional micro/nanocarbon structures that have not previously been technically possible.展开更多
Crystalline carbon nanowire arrays were fabricated taking advantage of near-field electrospinning and stress decyanation.A novel fabrication method for carbon nanowires with radii ranging from~2.15μm down to~25 nm wa...Crystalline carbon nanowire arrays were fabricated taking advantage of near-field electrospinning and stress decyanation.A novel fabrication method for carbon nanowires with radii ranging from~2.15μm down to~25 nm was developed based on implementing nitrogen pretreatment on the silica surface and then aligning polymer nanofibers during near-field electrospinning at an ultralow voltage.Stress decyanation was implemented by subsequently pyrolyzing a polymer nanofiber array on the silica surface at 1000°C for 1 h in an N_(2)atmosphere,thus obtaining a crystalline carbon nanowire array with a nanostructured surface.Various crystalline nanostructures were fabricated on the nanowire surface,and their electrochemical performance was evaluated by cyclic voltammetry(CV)and electrochemical impedance spectroscopy(EIS).Crystalline carbon wires with diameters ranging from micrometers to submicrometers displayed carbon nanoelectrode-like behavior with their CV curve having a sigmoidal shape.A highly crystalline carbon nanowire array showed distinct behavior,having a monotonically increasing straight line as its CV curve and a semicircular EIS spectrum;these results demonstrated its ultrastable current,as determined by electron transfer.Furthermore,nanocrystalline-structured carbon wires with diameters of~305 nm displayed at least a fourfold higher peak current density during CV(4000 mA/m2)than highly crystalline carbon nanowires with diameters of~100 nm and porous microwires with diameters of~4.3μm.展开更多
基金supported by the National Natural Science Foundation of China(Nos.22278020,2177060378)the Program for Changjiang Scholars,Innovative Research Teams in Universities(No.IRT1205)the Fundamental Research Funds for the Central Universities(Nos.12060093063,XK1803-05).
文摘Electrocatalytic CO_(2) reduction reaction(ECO_(2)RR)converts CO_(2) to high-value chemical products and promotes the carbon cycle.Sulfur(S)-modified copper(Cu)and bismuth(Bi)-based catalysts have been recognized as promising catalysts for ECO_(2)RR.Both of them are highly active for selective formate generation,however,their poor stability and severe competing hydrogen evolution reaction(HER)remain challenging.Herein,S-doped Cu coated with Bi(Bi/Cu-S)is developed to improve ECO_(2)RR selectivity to formate.Bi/Cu-S/brass mesh(BM)electrode material for ECO_(2)RR was prepared by electrodepositing Bi on the surface of Cu-S/BM nanowires obtained from CuS/BM after the electroreduction.The Faradaic efficiency(FE)of the formate reaches the maximum of 94.3%at-0.9 V vs.reversible hydrogen electrode(RHE)with a partial current density as high as-50.7 mA·cm^(-2) and a yield of 30.7 mmol·h^(-1)·cm^(-2) under 0.5 M KHCO_(3) electrolyte.Meanwhile,the FE of formate is higher than 90%in the voltage range of-0.8 to-1.0 V vs.RHE.It also shows good stability at-0.9 V vs.RHE with the FE of formate remaining above 93%after a 10 h reaction.Density functional theory(DFT)calculations demonstrate that the Bi/Cu-S structure promotes the adsorption of CO_(2) and effectively inhibits HER by enhancing the adsorption of^(*)H to a great extent,improving the selective conversion of CO_(2) to formate.This work deepens the understanding of the mechanism of Cu-Bi-based catalysts and S-modified Cu-based catalysts in selective ECO_(2)RR to formate,and also provides a new strategy for catalyst design.
基金supported by the Natural Science Special(Special Post)Research Foundation of Guizhou University[Grant No.2023-038]Guizhou Provincial Science and Technology Projects(No.PTRC[2020]6007-2).
文摘To produce a three-dimensional micro/nanocarbon structure,a manufacturing design technique for sub-10 nm carbon fiber arrays on three-dimensional carbon micropillars has been developed;the method involves initiating electrostatic jetting,forming submicron-to-nanoscale PAN-based fibers,and maximizing the shrinkage from polyacrylonitrile(PAN)-based fibers to carbon fibers.Nanoforming and nanodepositing methods for polyacrylonitrilebased jet fibers as precursors of carbon fibers are proposed for the processing design of electrostatic jet initiation and for the forming design of submicron-to-nanoscale PAN-based fibers by establishing and analyzing mathematical models that include the diameter and tensile stress values of jet fibers and the electric field intensity values on the surfaces of carbon micropillars.In accordance with these methods,an array of jet fibers with diameters of~80 nm is experimentally formed based on the thinning of the electrospinning fluid on top of a dispensing needle,the poking of drum into an electrospinning droplet,and the controlling of the needle–drum distance.When converting thin PANbased jet fibers to carbon fibers,a pyrolysis method consisting of the suspension of jet nanofibers between carbon micropillars,the bond between the fibers and the surface of the carbon micropillar,and the control of micropillar spacing,stabilization temperature,and carbonation rate is presented to maximize the shrinkage from PAN-based fibers to carbon fibers and to form sub-10 nm carbon fiber arrays between three-dimensional carbon micropillars.The manufacturing design of a three-dimensional micro/nanocarbon structure can produce thin PAN-based jet nanofibers and nanofiber arrays aligned on micropillar surfaces,obtain shrinkage levels reaching 96%and incorporate sub-10 nm carbon fibers into three-dimensional carbon micropillars;these actions provide new research opportunities for correlated three-dimensional micro/nanocarbon structures that have not previously been technically possible.
基金This research was supported by the National Key R&D Program of China(2020YFB2009002)the National Natural Science Foundation of China(51875084)The support provided by the China Scholarship Council(CSC)during the visit of Jufeng Deng to the University of California,Irvine is acknowledged.
文摘Crystalline carbon nanowire arrays were fabricated taking advantage of near-field electrospinning and stress decyanation.A novel fabrication method for carbon nanowires with radii ranging from~2.15μm down to~25 nm was developed based on implementing nitrogen pretreatment on the silica surface and then aligning polymer nanofibers during near-field electrospinning at an ultralow voltage.Stress decyanation was implemented by subsequently pyrolyzing a polymer nanofiber array on the silica surface at 1000°C for 1 h in an N_(2)atmosphere,thus obtaining a crystalline carbon nanowire array with a nanostructured surface.Various crystalline nanostructures were fabricated on the nanowire surface,and their electrochemical performance was evaluated by cyclic voltammetry(CV)and electrochemical impedance spectroscopy(EIS).Crystalline carbon wires with diameters ranging from micrometers to submicrometers displayed carbon nanoelectrode-like behavior with their CV curve having a sigmoidal shape.A highly crystalline carbon nanowire array showed distinct behavior,having a monotonically increasing straight line as its CV curve and a semicircular EIS spectrum;these results demonstrated its ultrastable current,as determined by electron transfer.Furthermore,nanocrystalline-structured carbon wires with diameters of~305 nm displayed at least a fourfold higher peak current density during CV(4000 mA/m2)than highly crystalline carbon nanowires with diameters of~100 nm and porous microwires with diameters of~4.3μm.
