Highly surface electron-deficient Co_(9)S_(8) nanoarrays for enhanced oxygen evolution

Tailoring valence electron delocalization of transition metal center is of importance to achieve highly-active electrocatalysts for oxygen evolution reaction(OER).Herein,we demonstrate a“poor sulfur”route to synthesize surface electron-deficient Co_(9)S_(8) nanoarrays,where the binding energy(BE)of Co metal center is considerably higher than all reported Co_(9)S_(8)-based electrocatalysts.The resulting Co_(9)S_(8) electrocatalysts only require the overpotentials(h)of 265 and 326 mV at 10 and 100 mA cm^(-2) with a low Tafel slope of 56 mV dec^-(1) and a 60 hlasting stability in alkaline media.The OER kinetics are greatly expedited with a low reaction activation energy of 27.9 kJ mol^-(1) as well as abundant OOH*key intermediates(24%),thus exhibiting excellent catalytic performances.The surface electron-deficient engineering gives an available strategy to improve the catalytic activity of other advanced non-noble electrocatalysts.

Integrated Ni-P-S nanosheets array as superior electrocatalysts for hydrogen generation

Searching for efficient and robust non-noble electrocatalysts for hydrogen generation is extremely desirable for future green energy systems.Here, we present the synthesis of integrated Ni-P-S nanosheets array including Ni_2P and NiS on nickel foam by a simple simultaneous phosphorization and sulfurization strategy. The resultant sample with optimal composition exhibits superior electrocatalytic performance for hydrogen evolution reaction(HER) in a wide pH range. In alkaline media, it can generate current densities of 10, 20 and 100 mA cm^(-2) at low overpotentials of only-101.9,-142.0 and-207.8 mV with robust durability. It still exhibits high electrocatalytic activities even in acid or neutral media. Such superior electrocatalytic performances can be mainly attributed to the synergistic enhancement of the hybrid Ni-P-S nanosheets array with integration microstructure. The kind of catalyst gives a new insight on achieving efficient and robust hydrogen generation.

TopoisomeraseⅡαGene as a Marker for Prognostic Prediction of Hepatocellular Carcinoma:A Bioinformatics Analysis

Objective To investigate the expression of topoisomeraseⅡα(TOP2α)in hepatocellular carcinoma(HCC)and its role in predicting prognosis of HCC patients.Methods We used HCC-related datasets in UALCAN,HCCDB,and cBioPortal databases to analyze the expression and mutation of TOP2αand its co-expressed genes in HCC tissues.GO function and KEGG pathway enrichment of TOP2αand its co-expressed genes were identified.The TIMER database was used to analyze infiltration levels of immune cells in HCC.The impacts of TOP2αand its co-expression genes and the infiltrated immune cells on the survival of HCC patients were assayed by Kaplan-Meier plotter analysis.Results TOP2αand its co-expression genes were highly expressed in HCC(P<0.001)and detrimental to overall survival of HCC patients(P<0.001).TOP2αand its co-expression genes were mainly involved in cell mitosis and proliferation,and cell cycle pathway(ID:hsa04110,P=0.001945).TOP2αand its co-expression genes were mutated in HCC and the mutations were significantly detrimental to overall survival(P=0.0247)and disease-free survival(P=0.0265)of HCC patients.High TOP2αexpression was positively correlated with the infiltration of B cell(r=0.459,P<0.01),CD8^(+)T cell(r=0.312,P<0.01),CD4^(+)T cell(r=0.370,P<0.01),macrophage(r=0.459,P<0.01),neutrophil(r=0.405,P<0.01),and dendritic cell(r=0.473,P<0.01)in HCC.The CD8^(+)T cell infiltration significantly prolonged the 3-and 5-year survival of HCC patients(all P<0.05),and CD4^(+)T cell infiltration significantly shortened the 3-,5-,and 10-year survival of HCC patients(all P<0.05).Conclusion TOP2αmay be an oncogene,which was associated with poor prognosis of HCC patients and could be used as a biomarker for the prognostic prediction of HCC.

Synthesis,biological activities and 3D-QSAR studies of(R)-2-phenyl-4,5-dihydrothiazole-4-carboxamide derivatives containing a sulfur ether moiety

A series of(R)-2-phenyl-4,5-dihydrothiazole-4-carboxamide derivatives containing a sulfur ether moiety were synthesized and characterized on the basis of NMR and elemental analysis(EA). The crystal structure of(R)-N-(2-methyl-1-(methylthio)propan-2-yl)-2-(4-nitrophenyl)-4,5-dihydrothiazole-4-carboxamide(13 d) was determined to show R configuration. The bioasssy results indicated that most title compounds displayed good and broad spectrum antifungal activities against several phytopathogenic fungi. The structure activity relationships were discussed. Based on the antifungal activity of title compounds against Phytophthora capsici, a CoMSIA calculation was performed to establish a 3 D-QSAR model, which revealed that electrostatic and hydrophobic fields were the two most significant factors for antifungal activity. According to the established 3D-QSAR model, structure optimization was carried out to find(R)-N-((R)-1-(methylthio)propan-2-yl)-2-(p-tolyl)-4,5-dihydrothiazole-4-carboxamide(15 h)with excellent activity against Phytophthora capsici, thus emerging as a new lead compound for novel antiphytopathogenic fungus agent development.

Recent progress on the modification of high nickel contentNCM:Coating,doping,and single crystallization

High nickel content layered cathodes,represented by NCM(LiNi_(x)Co_(y)Mn_(z)O_(2),x+y+z=1),are now widely employed in the market of electric vehicles,owing to their high energy density.With the gradual increase of nickel content and capacity,the issues on cycling life and safety become more serious.In this review,various strategies for improving the performance of high nickel NCM are summarized on the aspects of surface coating,ionic doping,and singlecrystal NCM.The coating strategy was separately described according to the physical property of coating species,including inert material coating,Li^(+)-conductor coating,electronic conductor coating,and mixed conductor coating.These coating species help to suppress the interfacial oxidation of electrolytes by NCM,improving the cycling life and safety.The elemental doping in the crystal lattice of NCM is then presented in the aspects of cation,anion,and mixed-ion doping,which are beneficial to stabilize the layered structure during charge–discharge and so promote the electrochemical performance.In quite recent years,the strategy of single-crystal NCM was demonstrated to be a promising pathway,owing to the dramatically reduced surface area and grain boundary.Finally,the remaining unsolved challenges and future strategies for further development of NCM cathode materials are outlined.