WS2 nanosheets were prepared by the solvent-thermal method in the presence of n-butyl lithium, then the exfoliation under the condition of ultrasound. The formed WS2 nanosheets were conjugated with thiol-modified poly...WS2 nanosheets were prepared by the solvent-thermal method in the presence of n-butyl lithium, then the exfoliation under the condition of ultrasound. The formed WS2 nanosheets were conjugated with thiol-modified polyethylene glycol (PEG-SH) to improve the biocompatibility. The nanosheets (WS2- PEG) were able to inhibit the growth of a model HeLa cancer cell line in vitro due to the high photothermal conversion efficiency of ~35% irradiated by an 808 nm laser (1 W/cm^2). As a proof of concept, WS2-PEG nanosheets with the better X-ray attenuation property than the clinical computed tomography (CT) contrast agent (lohexol) could be performed for CT imaging of the lymph vessel.展开更多
In this paper,the determination of Thiram fungicide by a novel modified screen-printed carbon electrode(SPCE)fabricated modifying the working electrode(WE)with 2D-GO/WS2nanohybrid composites,is reported.Scanning elect...In this paper,the determination of Thiram fungicide by a novel modified screen-printed carbon electrode(SPCE)fabricated modifying the working electrode(WE)with 2D-GO/WS2nanohybrid composites,is reported.Scanning electron microscopy(SEM),Raman spectroscopy,and fluorescence analysis(PL)were used to reveal the morphological and microstructural characteristics of the 2D-GO/WS2 nanohybrids with different graphene oxide:tungsten disulphide(GO:WS_(2))ratio.Electrochemical characterization demonstrated that the 2D-WS2/GO nanohybrids having a GO:WS_(2)ratio=2:1 shows the highest electrocatalytic activity towards oxidation of Thiram.The developed sensor permits the quantification of Thiram in the linear range 0.083-0.33μM with a limit of detection(LOD)of 0.02μM,which is below the legal limits for this fungicide in drinking water or foods.展开更多
Photoreduction of hexavalent uranium(U(VI))by semiconductor provides a novel and effective avenue for uranium extraction.Unfortunately,the traditional metal oxide and sulfide semiconductors suffer from the lack of con...Photoreduction of hexavalent uranium(U(VI))by semiconductor provides a novel and effective avenue for uranium extraction.Unfortunately,the traditional metal oxide and sulfide semiconductors suffer from the lack of confinement sites to U(VI),which resulted in the long period(~1 h)to achieve a high U(VI)extraction efficiency of>90%.Herein,we successfully constructed WS2 nanosheets and created in-situ oxidized domains on the surfaces(O-WS_(2))to promote the uranium extraction and the corresponding removal kinetics.In this system,the O_(7.7-)WS_(2) nanosheets exhibited a considerable U(VI)extraction efficiency of>90%within 20 min in 8 mg·L^(–1) U(VI)-containing solution,which represented the highly efficient U(VI)removal performance.In 200 mg·L^(–1) U(VI)-containing solution,the O7.7-WS2 nanosheets exhibited an extraction capacity of 652.4 mg·g^(-1).The mechanism study revealed that the oxidized surface tended to trap hydrogen atom and in-situ form hydroxyl groups in defect sites.Evidenced by a series of experiment,such as kinetic isotope effect,1H nuclear magnetic resonance(NMR)spectra,and X-ray absorption near-edge structure(XANES)spectra,the in-situ formed hydroxyl groups participated in the uranium reduction,which dramatically enhanced uranium extraction kinetics and efficiency.展开更多
基金partially supported by National Natural Science Foundation of China (Nos.21271130,21371122,and 11275050)Program for Changjiang Scholars and Innovative Research Team in University (No.IRT1269)+4 种基金Shanghai Science and Technology Development Fund (Nos.12ZR1421800 and 13520502800)Shanghai Pujiang Program (No.13PJ1406600)Shanghai Municipal Education Commission (No.13ZZ110)Shanghai Normal University (Nos.DXL122 and SK201339)International Joint Laboratory on Resource Chemistry (IJLRC)
文摘WS2 nanosheets were prepared by the solvent-thermal method in the presence of n-butyl lithium, then the exfoliation under the condition of ultrasound. The formed WS2 nanosheets were conjugated with thiol-modified polyethylene glycol (PEG-SH) to improve the biocompatibility. The nanosheets (WS2- PEG) were able to inhibit the growth of a model HeLa cancer cell line in vitro due to the high photothermal conversion efficiency of ~35% irradiated by an 808 nm laser (1 W/cm^2). As a proof of concept, WS2-PEG nanosheets with the better X-ray attenuation property than the clinical computed tomography (CT) contrast agent (lohexol) could be performed for CT imaging of the lymph vessel.
基金supported by the European Union (Next Generation EU)through the MUR-PNRR project SAMOTHRACE (No.ECS00000022)。
文摘In this paper,the determination of Thiram fungicide by a novel modified screen-printed carbon electrode(SPCE)fabricated modifying the working electrode(WE)with 2D-GO/WS2nanohybrid composites,is reported.Scanning electron microscopy(SEM),Raman spectroscopy,and fluorescence analysis(PL)were used to reveal the morphological and microstructural characteristics of the 2D-GO/WS2 nanohybrids with different graphene oxide:tungsten disulphide(GO:WS_(2))ratio.Electrochemical characterization demonstrated that the 2D-WS2/GO nanohybrids having a GO:WS_(2)ratio=2:1 shows the highest electrocatalytic activity towards oxidation of Thiram.The developed sensor permits the quantification of Thiram in the linear range 0.083-0.33μM with a limit of detection(LOD)of 0.02μM,which is below the legal limits for this fungicide in drinking water or foods.
基金supported by the National Natural Science Foundation of China(NSFC)(Nos.21902130,21906154,and 21976147)Sichuan Science and Technology Program(Nos.2022YFG0371,2020JDJQ0060,and 2020JDRC0089)Natural Science Foundation of Anhui province(No.2008085QB81)。
文摘Photoreduction of hexavalent uranium(U(VI))by semiconductor provides a novel and effective avenue for uranium extraction.Unfortunately,the traditional metal oxide and sulfide semiconductors suffer from the lack of confinement sites to U(VI),which resulted in the long period(~1 h)to achieve a high U(VI)extraction efficiency of>90%.Herein,we successfully constructed WS2 nanosheets and created in-situ oxidized domains on the surfaces(O-WS_(2))to promote the uranium extraction and the corresponding removal kinetics.In this system,the O_(7.7-)WS_(2) nanosheets exhibited a considerable U(VI)extraction efficiency of>90%within 20 min in 8 mg·L^(–1) U(VI)-containing solution,which represented the highly efficient U(VI)removal performance.In 200 mg·L^(–1) U(VI)-containing solution,the O7.7-WS2 nanosheets exhibited an extraction capacity of 652.4 mg·g^(-1).The mechanism study revealed that the oxidized surface tended to trap hydrogen atom and in-situ form hydroxyl groups in defect sites.Evidenced by a series of experiment,such as kinetic isotope effect,1H nuclear magnetic resonance(NMR)spectra,and X-ray absorption near-edge structure(XANES)spectra,the in-situ formed hydroxyl groups participated in the uranium reduction,which dramatically enhanced uranium extraction kinetics and efficiency.
