Your search keyword '"Li, Jinze"' showing total 3 results

1. Synthesis of AgInS2 QDs-MoS2/GO composite with enhanced interfacial charge separation for efficient photocatalytic degradation of tetracycline and CO2 reduction.

Author

Wang, Huijie, Li, Jinze, Wan, Yang, Nazir, Ahsan, Song, Xianghai, Huo, Pengwei, and Wang, Huiqin

Subjects

*TETRACYCLINE, *PHOTODEGRADATION, *TETRACYCLINES, *CARBON dioxide, *PHOTOCATALYSTS, *SMALL molecules

Abstract

The interfacial regulation strategy between semiconductors can effectively promote the separation efficiency of photogenerated carriers and enhance photocatalytic activity under the synergistic effect. Herein, AgInS 2 QDs-MoS 2 /GO (AIS-MS/GO) composites were prepared by interfacial coupling of AgInS 2 QDs (AIS), hierarchical MoS 2 and ultrathin GO. Ultrathin GO successfully solved the agglomeration problem of AIS and hierarchical MoS 2. Moreover, the photogenerated carriers were effectively separated and transferred under the synergistic effect of the AIS-MS heterojunction and ultrathin GO, thus promoting tetracycline (TC) degradation and CO 2 reduction performance. The degradation rate of tetracycline (TC) reached 96.5 %, and the yields of CO and CH 4 in the CO 2 reduction products reached 52.6 and 28.5 μmol g–1, respectively, when using the optimized photocatalyst. In-situ FTIR analysis indicated that TC is gradually degraded by small molecules on the composite surface, and has excellent dissociation ability of water molecules during the CO 2 reduction process. This work provides a new vision for the rational design of heterojunction-based photocatalysts using the interfacial regulation strategy for enhancing interfacial charge separation and photocatalytic performance. [Display omitted] • AIS-MS/GO composites were prepared via the interfacial regulation strategy. • The photogenerated carriers were effectively separated and transferred under synergistic and interfacial effects. • The aggregation problem of AIS and hierarchical MoS 2 was effectively solved. • AIS-MS/GO composites achieve a 96.5 % TC degradation rate and 35.1 % selectivity for CH 4. [ABSTRACT FROM AUTHOR]

Published

2023

2. Chemical precipitation synthesis of porous Ni2P2O7 nanowires for supercapacitor.

Author

Zhou, Yaju, Liu, Chongyang, Li, Xin, Sun, Linlin, Wu, Dongyao, Li, Jinze, Huo, Pengwei, and Wang, Huiqin

Subjects

*SUPERCAPACITOR electrodes, *SUPERCAPACITORS, *NANOWIRES, *CHEMICAL synthesis, *ENERGY density, *ENERGY storage, *POROUS electrodes, *CARBON nanotubes

Abstract

Abstract Supercapacitor is a new energy storage device between traditional capacitor and rechargeable battery. Not only has the characteristics of fast charging and discharging of capacitor, but also has the characteristics of energy storage of battery. The electrochemical tests indicate that the electrode in view of porous Ni 2 P 2 O 7 nanowires (NWs) has a specific capacitance of 772.5 Fg-1 at current density 1 Ag-1. Furthermore, porous Ni 2 P 2 O 7 NWs have been successfully applied to construct all-solid hybrid supercapacitors. Carbon nanotubes (CNT) and easily treated nickel pyrophosphate (Ni 2 P 2 O 7) are considered as electrode materials for supercapacitors under alkaline conditions. The equipment has a high energy density of 6.25 mWh cm−2 and good cycle stability of 94% capacitance retention after 3000 cycles, which identifies that porous Ni 2 P 2 O 7 nanowires are promising supercapacitor active materials. Highlights • A novel intercalated porous Ni 2 P 2 O 7 nanowires was prepared by simple chemical precipitation method. • The intercalated porous Ni 2 P 2 O 7 nanowires as new electrode materials exhibited great electrochemical properties. • Ni 2 P 2 O 7 //CNT ASC device is a promising material for fiber supercapacitors and electronic applications. [ABSTRACT FROM AUTHOR]

Published

2019

3. Preparation of 3D porous g-C3N4@V2O5 composite electrode via simple calcination and chemical precipitation for supercapacitors.

Author

Zhou, Yaju, Sun, Linlin, Wu, Dongyao, Li, Xin, Li, Jinze, Huo, Pengwei, Wang, Huiqin, and Yan, Yongsheng

Subjects

*SUPERCAPACITOR electrodes, *ELECTRODE potential, *FIELD emission electron microscopy, *ELECTRODES, *CHEMICAL stability, *ELECTRON transport

Abstract

The unique three-dimensional (3D) porous structure of graphite carbon nitride (g-C 3 N 4) and vanadium pentoxide (V 2 O 5) was prepared by an environmentally friendly one-step solvothermal method, and its electrochemical performance was assessed. Importantly, g-C 3 N 4 is a low cost material with excellent chemical stability, and it supports the vertical charge transfer during the charge-discharge process, which promotes electronic transmission along this direction. In addition, V 2 O 5 has good theoretical capacitance and is deemed as a potential electrode material for next-generation supercapacitors. Field emission scanning electron microscopy of the nanocomposite revealed a 3D porous morphology for g-C 3 N 4 (3D PCN) and a spherical morphology for V 2 O 5. This study estimated the viability of the graphite carbon nitride-based nanocomposite PCN@V 2 O 5 as a new catalyst in the supercapacitor (SC) anodes. A series of SC anodes with different catalyst loadings were produced. The electrochemical behavior of the SC anodes was calculated by cyclic voltammetry (CV), charge-discharge and cycling test. When test in electrochemical performance, the ratio of PCN:V 2 O 5 is lower than 1:1 and 3D PCN@V 2 O 5 exhibits a lower specific capacity, the ratio of PCN:V 2 O 5 is higher than 1:1 that most of the pores in 3D porous g-C 3 N 4 are covered that reduces the electron transport rate and results in a lower specific capacity. Overall, 3D PCN@V 2 O 5 has higher specific capacity (457 Fg-1 at 0.5 Ag-1) and better cycling performance (approximately 84% after 500 cycles). This attractive performance indicates that 3D PCN@V 2 O 5 could be used as potential electrode materials for supercapacitors. • A novel 3D porous PCN@V 2 O 5 was prepared by simple chemical precipitation method. • The 3D porous PCN@V 2 O 5 as new electrode materials exhibited great electrochemical properties. • The 3D porous PCN@V 2 O 5 products are potential supercapacitor electrode materials for supercapacitors. [ABSTRACT FROM AUTHOR]

Published

2020