The immobilization of cytochrome c or horseradish peroxidase at the sulfur-modified gold electrode exhibits a rapid electron transfer behavior because of its specific orientation on the electrode surface and the inter...The immobilization of cytochrome c or horseradish peroxidase at the sulfur-modified gold electrode exhibits a rapid electron transfer behavior because of its specific orientation on the electrode surface and the interaction between cytochrome c or horseradish peroxidase and sulfur-modified on the surface of the Au electrode.展开更多
CO_(2)electroreduction(CO_(2)RR)represents a promising negative-carbon technology,which is in urgent need for efficient and high-selectivity catalysts.Here,a support control strategy is employed for precise surface en...CO_(2)electroreduction(CO_(2)RR)represents a promising negative-carbon technology,which is in urgent need for efficient and high-selectivity catalysts.Here,a support control strategy is employed for precise surface engineering of charge-asymmetry nanocluster catalyst(CuZnSCN),in which zinc and copper atoms together form a metal cluster loaded on sulfur and nitrogen co-etched carbon matrix.The synergistic promotion mechanism of CO_(2)RR by Cu–Zn atom interactions and sulfur–nitrogen atom doping was investigated.A CO partial current density of 74.1 mA cm^(-2)was achieved in an alkaline electrolyte,as well as a considerable CO Faraday efficiency of 97.7%.In situ XAS(X-ray absorption spectroscopy)showed that the stabilization of Cu^(+)and Zn^(2+)species in the nanoclusters and doped sulfur atoms during the CO_(2)RR process contributes to the sustained adsorption of protons and the generation and conversion of the CO.This work verifies the possibility of metal-support and intermetallic interactions to synergistically enhance electrochemical catalytic performance and provides ideas for further bimetallic cluster catalyst development.展开更多
Lithium-oxygen(Li-O) battery is considered as one of the most promising alternatives because of its ultrahigh theoretical energy density. However, their cycling stability is severely restricted by the uncontrollable d...Lithium-oxygen(Li-O) battery is considered as one of the most promising alternatives because of its ultrahigh theoretical energy density. However, their cycling stability is severely restricted by the uncontrollable dendrite growth and serious oxygen corrosion issue on Li surface. Herein, a sulfur-modified Li surface can be successfully constructed via chemical reaction of guanylthiourea(GTU) molecule on Li,which can induce the selectively fast decomposition of lithium bis(trifluoromethanesulfonyl)imide(LiTFSI) to form a smooth and stable inorganics-rich solid-electrolyte interphase(IR-SEI) during the subsequent electrochemical process. Such an IR-SEI cannot only offer a highly reversible and stable Li plating/stripping chemistry with dendrite-free property(10 mA cm^(-2)-10 mAh cm^(-2), > 0.5 years;3 mA cm^(-2)-3 m Ah cm^(-2), > 1 year) but also endows the Li metal an anti-oxygen corrosion function, thereby significantly improving the cycling stability of Li-Obatteries. This work provides a new idea for constructing functional solid-electrolyte interphase(SEI) to achieve highly stable Li metal anode.展开更多
基金Supported by the National Natural Science Foundation of China( No20573045) the "863"Program of China( No2006AA06Z321)
文摘The immobilization of cytochrome c or horseradish peroxidase at the sulfur-modified gold electrode exhibits a rapid electron transfer behavior because of its specific orientation on the electrode surface and the interaction between cytochrome c or horseradish peroxidase and sulfur-modified on the surface of the Au electrode.
基金financially supported by the National Natural Science Foundation of China(No.22375019)Beijing Institute of Technology Research Fund Program for Young Scholars(No.3090012221909)
文摘CO_(2)electroreduction(CO_(2)RR)represents a promising negative-carbon technology,which is in urgent need for efficient and high-selectivity catalysts.Here,a support control strategy is employed for precise surface engineering of charge-asymmetry nanocluster catalyst(CuZnSCN),in which zinc and copper atoms together form a metal cluster loaded on sulfur and nitrogen co-etched carbon matrix.The synergistic promotion mechanism of CO_(2)RR by Cu–Zn atom interactions and sulfur–nitrogen atom doping was investigated.A CO partial current density of 74.1 mA cm^(-2)was achieved in an alkaline electrolyte,as well as a considerable CO Faraday efficiency of 97.7%.In situ XAS(X-ray absorption spectroscopy)showed that the stabilization of Cu^(+)and Zn^(2+)species in the nanoclusters and doped sulfur atoms during the CO_(2)RR process contributes to the sustained adsorption of protons and the generation and conversion of the CO.This work verifies the possibility of metal-support and intermetallic interactions to synergistically enhance electrochemical catalytic performance and provides ideas for further bimetallic cluster catalyst development.
基金the financial support from the National Natural Science Foundation of China(U1805254,21773192,22072117,22179112)。
文摘Lithium-oxygen(Li-O) battery is considered as one of the most promising alternatives because of its ultrahigh theoretical energy density. However, their cycling stability is severely restricted by the uncontrollable dendrite growth and serious oxygen corrosion issue on Li surface. Herein, a sulfur-modified Li surface can be successfully constructed via chemical reaction of guanylthiourea(GTU) molecule on Li,which can induce the selectively fast decomposition of lithium bis(trifluoromethanesulfonyl)imide(LiTFSI) to form a smooth and stable inorganics-rich solid-electrolyte interphase(IR-SEI) during the subsequent electrochemical process. Such an IR-SEI cannot only offer a highly reversible and stable Li plating/stripping chemistry with dendrite-free property(10 mA cm^(-2)-10 mAh cm^(-2), > 0.5 years;3 mA cm^(-2)-3 m Ah cm^(-2), > 1 year) but also endows the Li metal an anti-oxygen corrosion function, thereby significantly improving the cycling stability of Li-Obatteries. This work provides a new idea for constructing functional solid-electrolyte interphase(SEI) to achieve highly stable Li metal anode.
