Co-Modification of commercial TiO anode by combining a solid electrolyte with pitch-derived carbon to boost cyclability and rate capabilities.

The bad electrochemical performance circumscribes the application of commercial TiO (c-TiO) anodes in Li-ion batteries. Carbon coating could ameliorate the electronic conductivity of TiO, but the ionic conductivity is still inferior. Herein, a co-modification method was proposed by combining the solid electrolyte of lithium magnesium silicate (LMS) with pitch-derived carbon to concurrently meliorate the electronic and ionic conductivities of c-TiO.

A uniform few-layered carbon coating derived from self-assembled carboxylate monolayers capable of promoting the rate properties and durability of commercial TiO.

The poor cyclability and rate property of commercial TiO (c-TiO) hinder its utilization in lithium-ion batteries (LIBs). Coating carbon is one of the ways to ameliorate the electrochemical performance. However, how to effectively form a uniform thin carbon coating is still a challenge.

Combined Modification of Dual-Phase LiTiO-TiO by Lithium Zirconates to Optimize Rate Capabilities and Cyclability.

The low electrical conductivity and ordinary lithium-ion transfer capability of LiTiO restrict its application to some degree. In this work, dual-phase LiTiO-TiO (LTOT) was modified by composite zirconates of LiZrO, LiZrO (LZO) to boost the rate capabilities and cyclability. When the homogeneous mixture of LiNO, Zr(NO)·5HO and LTOT was roasted at 700 °C for 5 h, the obtained composite achieved a superior reversible capacity of 183.

Uniform Surface Modification of LiZnTiO by Liquated NaMoO To Boost Electrochemical Performance.

Poor ionic and electronic conductivities are the key issues to affect the electrochemical performance of LiZnTiO (LZTO). In view of the water solubility, low melting point, good electrical conductivity, and wettability to LZTO, NaMoO (NMO) was first selected to modify LZTO via simply mixing LZTO in NMO water solution followed by calcining the dried mixture at 750 °C for 5 h. The electrochemical performance of LZTO could be enhanced by adjusting the content of NMO, and the modified LZTO with 2 wt % NMO exhibited the most excellent rate capabilities (achieving lithiation capacities of 225.

Ionic Conductor of LiSiO as an Effective Dual-Functional Modifier To Optimize the Electrochemical Performance of LiTiO for High-Performance Li-Ion Batteries.

Ionic conductor of LiSiO (LSO) was used as an effective modifier to fabricate surface-modified LiTiO (LTO) via simply mixing followed by sintering at 750 °C in air. The electrochemical performance of LTO was enhanced by merely adjusting the mass ratio of LTO/LSO, and the LTO/LSO composite with 0.51 wt % LSO exhibited outstanding rate capabilities (achieving reversible capacities of 163.

Simple preparation of carbon nanofibers with graphene layers perpendicular to the length direction and the excellent li-ion storage performance.

Sulfur-containing carbon nanofibers with the graphene layers approximately vertical to the fiber axis were prepared by a simple reaction between thiophene and sulfur at 550 °C in stainless steel autoclaves without using any templates. The formation mechanism was discussed briefly, and the potential application as anode material for lithium-ion batteries was tentatively investigated. The carbon nanofibers exhibit a stable reversible capacity of 676.

Carbon-coated Fe-Mn-O composites as promising anode materials for lithium-ion batteries.

Fe-Mn-O composite oxides with various Fe/Mn molar ratios were prepared by a simple coprecipitation method followed by calcining at 600 °C, and carbon-coated oxides were obtained by pyrolyzing pyrrole at 550 °C. The cycling and rate performance of the oxides as anode materials are greatly associated with the Fe/Mn molar ratio. The carbon-coated oxides with a molar ratio of 2:1 exhibit a stable reversible capacity of 651.

Enhanced electrochemical performance of FeWO4 by coating nitrogen-doped carbon.

FeWO4 (FWO) nanocrystals were prepared at 180 °C by a simple hydrothermal method, and carbon-coated FWO (FWO/C) was obtained at 550 °C using pyrrole as a carbon source. The FWO/C obtained from the product hydrothermally treated for 5 h exhibits reversible capacities of 771.6, 743.

Large scale synthesis and gas-sensing properties of anatase TiO2 three-dimensional hierarchical nanostructures.

Three-dimensional (3D) crystalline anatase titanium dioxide (TiO(2)) hierarchical nanostructures were synthesized through a facile and controlled hydrothermal and after-annealing process. The formation mechanism for the anatase TiO(2) 3D hierarchical nanostructures was investigated in detail. The 3D hierarchical nanostructures morphologies are formed by self-organization of several tens of radially distributed thin petals with a thickness of several nanometers with a larger surface area.

Sol-gel growth of hexagonal faceted ZnO prism quantum dots with polar surfaces for enhanced photocatalytic activity.

The hexagonal faceted ZnO quantum dots (QDs) about 3-4 nm have been prepared via a sol-gel route by using oleic acid (OA) as the capping agent. It is revealed by electron diffraction patterns and high resolution transmission electron microscopy lattice images that the profile surfaces of the highly crystalline ZnO QDs are mainly composed of {100} planes, with the Zn-terminated (001) faces and the opposite (001) faces presented as polar planes. Compared with spherical ZnO QDs, the hexagonal faceted ZnO QDs show enhanced photocatalytic activity for photocatalytic decomposition of methylene blue.

Anti-endotoxic shock effects of cyproheptadine in rats.

Objective: To investigate the antagonistic effect and mechanism of the effect of cyproheptadine (Cyp) on endotoxic shock in rats.

Methods: Endotoxic shock was produced in rats by i.v.