Structural stability and ion migration of Li_(2)MnO_(3) cathode material under high pressures

Some special fields,such as deep-sea exploration,require batteries and their electrode materials to withstand extremely high pressure.As the cathode material has the highest energy density,Li-excess Mn-based materials are also likely to be utilized in such an environment.However,the effect of pressure on the crystal structure and migration barrier of this kind of material is still not clear at present.Therefore,in this study,we investigate the properties of the matrix material of Li-excess Mn-based material,Li_(2)MnO_(3),under high pressure.The equation of state,bulk modulus,and steady-state volume of Li_(2)MnO_(3) are predicted by the method of first principles calculation.The calculations of unit cells at different pressures reveal that the cell parameters suffer anisotropic compression under high pressure.During compression,Li-O bond is more easily compressed than Mn-O bond.The results from the climbing image nudged elastic band(CINEB)method show that the energy barrier of Li^(+)migration in the lithium layer increases with pressure increasing.Our study can provide useful information for utilizing Li-excess Mn-based materials under high pressure.

MIL-101(Cr)-decorated Ti/TiO_(2) anode for electrochemical oxidation of aromatic pollutants from water

Hydroxyl radicals(·OH) generated on anode play a vital role in electrochemical oxidation(EO) of organic pollutants for water treatment. Inspired by the four-electron oxygen evolution reaction(OER), we supposed an anode-selection strategy to stabilize deeply oxidized states(*O and*OOH) which are beneficial to generating·OH. To verify the hypothesis, a candidate anode component(MIL-101(Cr), a well-known metal-organic framework with active variable-valence transition metal centers) was used to coat Ti/TiO_(2)plate to fabricate anodes. Compared to TiO_(2)(101) plane on undecorated anode surface, fast and complete removal of aniline and phenol, and improved energy utilization were achieved on MIL-101(Cr)-coatedTi/TiO_(2)anode. Mechanism investigation, including pollutant degradation pathways, showed the predominate contribution(69.60%–75.13%) of·OH in pollutant mineralization. Density functional theory(DFT)computations indicated Cr site in MIL-101(Cr) was more conducive to stabilizing*O and*OOH, leading to thermodynamical spontaneous generation of·OH. This work opens up an exciting avenue to explore·OH production, and supplies a useful guidance to the development of anode materials for EO process.

Effects of trifluoromethanesulfonic acid ligand on the Zinc-based catalysts for the acetylene hydration

Developing an efficient Zn-based catalyst modified with Trifluoromethanesulfonic acid(Tf OH)ligand is extremely desirable for the acetylene hydration reaction.In this paper,with the use of a simple impregnation method,a series of Zn-Tf OH/AC catalysts were synthesized,and the Zn-1.5Tf OH/AC catalyst demonstrated the optimal catalytic performance with 96%acetylene conversion in the hydration of acetylene.The X-ray absorption fine structure(XAFS)spectra of the fresh Zn-1.5Tf OH/AC catalysts demonstrated the establishment of the Zn-O_(4)coordination structure.According to the characterization results,Tf OH ligands effectively inhibited carbon accumulation and Zinc loss,improved acidic sites and the dispersion of active metal,and produced more catalytic active site.Furthermore,the hydration reaction mechanism of Zn-Tf OH/AC catalyst with Zn(OTf)_(2),Tf O-Zn Cl,and Tf O-Zn OH complex configurations was explored by the Density Functional Theory(DFT)method,which showed that the activation barrier increased sequentially TfO-ZnOH<Zn(OTf)_(2)<Tf O-Zn Cl.Importantly,the OH-in TfO-ZnOH is involved in the reaction and regenerated by the dissociation of H_(2)O,which lowers the energy barrier.This will provide a reference to design more efficient nonmercury catalysts for acetylene hydration.

Asymmetric synthesis of bedaquiline based on bimetallic activation and non-covalent interaction promotion strategies

Bedaquiline(BDQ),approved by Food and Drug Administration(FDA)in 2012 as the first anti-tuberculosis-specific drug in the last 40 years,is viewed as one of the world’s most promising treatments for tuberculosis(TB).Due to the stereoselective construction of the Csp^(3)–Csp^(3)bond with vicinal stereocenters of BDQ and its analogues being an unsolved challenge,there have not been any reports concerning its asymmetric synthesis for the current industrial production process until now.Herein,we have successfully developed a cooperative bimetallic system for the asymmetric synthesis of BDQ under the guidance of density functional theory(DFT)computations.Based on the optimized conditions,BDQ could be synthesized with excellent enantioselectivity(>99%ee)and diastereoselectivity(16:1 dr).A 5-g scale reaction was also conducted with comparably excellent results,showing its potential for industrial application.

Modulation of photocatalytic activity of SrBi_(2)Ta_(2)O_(9)nanosheets in NO removal by tuning facets exposure

Photocatalysts with exposure of different crystal facets often show great differences in their photocatalytic activities due to differences in surface atomic arrangement and coordination.Thus,the actual photoreaction mechanism of a specific crystal facet in photocatalysis deserves to be explored.In this paper,as a case study,Sr Bi_(2)Ta_(2)O_(9)photocatalyst with preferential facet exposure was explored for the photocatalytic removal of NO at a ppb level.The efficiency of NO removal was remarkably improved by tuning the crystal exposure facet with high(200)facet exposure ratio.Optimized exposure of(200)crystal facet in Sr Bi_(2)Ta_(2)O_(9)(SBT)by thermal calcination at 800℃(SBT-800)leads to the highest NO removal activity of51%under a 300 W Xe lamp for 20 min;under visible light,SBT 800 achieves a 5-fold enhancement in NO removal efficiency compared to its counterpart,SBT-900.Active species capture experiments prove that the superoxide radical·O_(2)-is the main active species for the photocatalytic removal of NO,and surface selective deposition experiments conclude that(200)is the main electron-rich crystal plane,based on which the results of density functional theory(DFT)computation reveal the Bi O terminated nature of(001)crystal plane,where the models with both Bi O and Ta O terminated(001)planes were created and computated.Mechanistic study reveals that Sr Bi_(2)Ta_(2)O_(9)with a larger exposure of(200)facet provides more active reduction sites,thereby reducing more O_(2)to·O_(2)-,which further oxidizes the adsorbed NO to NO_(2)-/NO_(3)-.The present work underlines the role of facet tuning in the photoactivity modulation for NO removal photocatalytically.