It is a challenge to develop single polymer-based photocatalyst for overall water splitting without adding sacrificial agents due to the insufficient driving force for charge separation and the lack of active sites of...It is a challenge to develop single polymer-based photocatalyst for overall water splitting without adding sacrificial agents due to the insufficient driving force for charge separation and the lack of active sites of organic polymer.Metal oxyhyroxides are widely acted as co-catalyst for photoelectrocatalysis oxygen evolution reaction.Here,we firstly report the peryleno[1,12-bcd]thiophene sulfone-based linear co-polymer PS-5 for photocatalytic overall water splitting by photo-depositing simple and low-cost cocatalyst FeOOH under the visible-light illumination.The density functional theory(DFT)calculations and experimental results indicated clearly that the oxygen vacancies-richβ-FeOOH can effectively promote the separation of photo-generated excitons and provide active sites for photocatalytic oxygen evolution reaction.As a result,the average H_(2)and O_(2)production rates of optimized PS-5/β-FeOOH-0.2M reach at~170 and~76.6μmol h^(-1)g^(-1),respectively,with a stoichiometric ratio at about 2:1.This work provides a simple and low-cost method for the preparation of overall water splitting system based on polymer photocatalyst.展开更多
A cobalt-based catalyst was directly photo-deposited on the surface of a widely used n-type nano-structured semiconductor(TiO_(2)).Different thicknesses of the TiO 2 films as well as different time of photo-deposition...A cobalt-based catalyst was directly photo-deposited on the surface of a widely used n-type nano-structured semiconductor(TiO_(2)).Different thicknesses of the TiO 2 films as well as different time of photo-deposition of the Co-based catalyst on TiO_(2) films have been optimized.It was found that the electrode with 3 layers of TiO_(2) film(in 8 m thickness) and 1 hour photo-deposition of the cobalt-based catalyst by light irradiation from a 500 W Xenon lamp gave the highest current density(~5 mA/cm^(2)).Using this cobalt-modified TiO_(2) film as a working electrode in an electrochemical device,highly efficient water oxidation has been demonstrated in a pH 7.0 aqueous solution with low overpotential.展开更多
The selective oxidation of methane under mild conditions remains the“Holy Grail of Catalysis”.The key to activating methane and inhibiting over-oxidation of target oxygenates lies in designing active centers.Copper ...The selective oxidation of methane under mild conditions remains the“Holy Grail of Catalysis”.The key to activating methane and inhibiting over-oxidation of target oxygenates lies in designing active centers.Copper nanoparticles were loaded onto TiO_(2) nanofibers using the photo-deposition method.The resulting catalysts were found to effectively convert methane into C1 oxygenated products under mild conditions.Compared with previously reported catalysts,it delivers a superior performance of up to 2510.7 mmol·g_(Cu)^(-1)·h^(-1) productivity with a selectivity of around 100%at 80℃for 5 min.Microstructure characterizations and density functional theory(DFT)calculations indicate that TiO_(2) in the mixed phase of anatase and rutile significantly increases the Cu^(+)/CuO ratio of the supported Cu species,and this ratio is linearly related to the formation rate of oxygen-containing species.The CuI site promotes the generation of active O species from H_(2)O_(2) dissociation on Cu_(2)O(111).These active O species reduce the energy barrier for breaking the C-H bond of CH_(4),thus boosting the catalytic activity.The methane conversion mechanism was proposed as a methyl radical pathway to form CH_(3)OH and CH_(3)OOH,and then the generated CH_(3)OH is further oxidized to HOCH_(2)OOH.展开更多
A facile and effective impregnation combined with photo-deposition approach was adopted to deposit cadmium sulfide(CdS)nanoparticles on CTF-1,a covalent triazine-based frameworks(CTFs).In this system,CTF-1 not only ac...A facile and effective impregnation combined with photo-deposition approach was adopted to deposit cadmium sulfide(CdS)nanoparticles on CTF-1,a covalent triazine-based frameworks(CTFs).In this system,CTF-1 not only acted as supporter but also served as photocatalyst and electron donor.The performance of the obtained CdS deposited CTF-1(CdS-CTF-1)nanocomposite was evaluated by H2 evolution reaction under visible light irradiation.As a result,CdS-CTF-1 exhibited high H2 production from water,far surpassing the Cd S/CTF-1 nanocomposite,in which Cd S was deposited via solvothermal method.The high activity of CdS-CTF-1 was attributed to the confined Cd S nanoparticles with small size,leading to expose more active sites.In addition,time-resolved spectroscopy indicated that the superior performance of Cd S-CTF-1 also can be ascribed to the fast electron transfer rate and injection efficiency(KET=0.18×10^9 s^-1,ηinj=39.38%)between Cd S and CTF-1 layers,which are 3.83 times faster and 4.84 times higher than that of Cd S/CTF-1 nanocomposite.This work represents the first example on using covalent organic frameworks(COFs)as a support and electron-donor for fabricating novel Cd S-COF nanocomposite system and its potential application in solar energy transformations.展开更多
基金supported by the National Natural Science Foundation of China(21788102,21971064,21772040)Shanghai Municipal Science and Technology Major Project(2018SHZDZX03)+1 种基金the Fundamental Research Funds for the Central Universities(222201717003,50321101918001)the Programme of Introducing Talents of Discipline to Universities(B16017)。
文摘It is a challenge to develop single polymer-based photocatalyst for overall water splitting without adding sacrificial agents due to the insufficient driving force for charge separation and the lack of active sites of organic polymer.Metal oxyhyroxides are widely acted as co-catalyst for photoelectrocatalysis oxygen evolution reaction.Here,we firstly report the peryleno[1,12-bcd]thiophene sulfone-based linear co-polymer PS-5 for photocatalytic overall water splitting by photo-depositing simple and low-cost cocatalyst FeOOH under the visible-light illumination.The density functional theory(DFT)calculations and experimental results indicated clearly that the oxygen vacancies-richβ-FeOOH can effectively promote the separation of photo-generated excitons and provide active sites for photocatalytic oxygen evolution reaction.As a result,the average H_(2)and O_(2)production rates of optimized PS-5/β-FeOOH-0.2M reach at~170 and~76.6μmol h^(-1)g^(-1),respectively,with a stoichiometric ratio at about 2:1.This work provides a simple and low-cost method for the preparation of overall water splitting system based on polymer photocatalyst.
基金supported by Swedish Energy Agency,the Knutand Alice Wallenberg Foundation,China Scholarship Council (CSC)the Natural Natural Science Foundation of China (21120102036)the National Basic Research Program of China (2009CB220009)
文摘A cobalt-based catalyst was directly photo-deposited on the surface of a widely used n-type nano-structured semiconductor(TiO_(2)).Different thicknesses of the TiO 2 films as well as different time of photo-deposition of the Co-based catalyst on TiO_(2) films have been optimized.It was found that the electrode with 3 layers of TiO_(2) film(in 8 m thickness) and 1 hour photo-deposition of the cobalt-based catalyst by light irradiation from a 500 W Xenon lamp gave the highest current density(~5 mA/cm^(2)).Using this cobalt-modified TiO_(2) film as a working electrode in an electrochemical device,highly efficient water oxidation has been demonstrated in a pH 7.0 aqueous solution with low overpotential.
基金supported by the National Natural Science Foundation of China(Nos.92145301,91845201,22002094,22102106,22309061)the Natural Science Foundation of Jilin Province(No.YDZJ202201ZYTS360).
文摘The selective oxidation of methane under mild conditions remains the“Holy Grail of Catalysis”.The key to activating methane and inhibiting over-oxidation of target oxygenates lies in designing active centers.Copper nanoparticles were loaded onto TiO_(2) nanofibers using the photo-deposition method.The resulting catalysts were found to effectively convert methane into C1 oxygenated products under mild conditions.Compared with previously reported catalysts,it delivers a superior performance of up to 2510.7 mmol·g_(Cu)^(-1)·h^(-1) productivity with a selectivity of around 100%at 80℃for 5 min.Microstructure characterizations and density functional theory(DFT)calculations indicate that TiO_(2) in the mixed phase of anatase and rutile significantly increases the Cu^(+)/CuO ratio of the supported Cu species,and this ratio is linearly related to the formation rate of oxygen-containing species.The CuI site promotes the generation of active O species from H_(2)O_(2) dissociation on Cu_(2)O(111).These active O species reduce the energy barrier for breaking the C-H bond of CH_(4),thus boosting the catalytic activity.The methane conversion mechanism was proposed as a methyl radical pathway to form CH_(3)OH and CH_(3)OOH,and then the generated CH_(3)OH is further oxidized to HOCH_(2)OOH.
基金financially supported by the National Natural Science Foundation of China(51938007,51878325,51868050,51622806 and 51868052)the Natural Science Foundation of Jiangxi Province(20162BCB22017,20165BCB18008,20171ACB20017,and 20171BAB206049)+1 种基金the Ph.D.research startup foundation of Nanchang Hangkong University(EA201802367)the foundation of Jiangxi Scientific Committee(DA201902167)for financial support.
文摘A facile and effective impregnation combined with photo-deposition approach was adopted to deposit cadmium sulfide(CdS)nanoparticles on CTF-1,a covalent triazine-based frameworks(CTFs).In this system,CTF-1 not only acted as supporter but also served as photocatalyst and electron donor.The performance of the obtained CdS deposited CTF-1(CdS-CTF-1)nanocomposite was evaluated by H2 evolution reaction under visible light irradiation.As a result,CdS-CTF-1 exhibited high H2 production from water,far surpassing the Cd S/CTF-1 nanocomposite,in which Cd S was deposited via solvothermal method.The high activity of CdS-CTF-1 was attributed to the confined Cd S nanoparticles with small size,leading to expose more active sites.In addition,time-resolved spectroscopy indicated that the superior performance of Cd S-CTF-1 also can be ascribed to the fast electron transfer rate and injection efficiency(KET=0.18×10^9 s^-1,ηinj=39.38%)between Cd S and CTF-1 layers,which are 3.83 times faster and 4.84 times higher than that of Cd S/CTF-1 nanocomposite.This work represents the first example on using covalent organic frameworks(COFs)as a support and electron-donor for fabricating novel Cd S-COF nanocomposite system and its potential application in solar energy transformations.