Your search keyword '"Zhifeng, Xu"' showing total 4 results

1. Nitrogen and Phosphorus-codoped Carbon Nanotube/Fe2P Nanoparticle Hybrids Toward Efficient Oxygen Reduction and Zinc-air Batteries.

Author

Ruixiang Wang, Yuanliang Yuan, Xiaocong Zhong, Yirui Zhu, Jiaming Liu, Yongmin Xie, Shuiping Zhong, and Zhifeng Xu

Subjects

OXYGEN reduction, CARBON nanotubes, METAL nanoparticles, REDUCTION potential, METAL compounds, CYCLIC voltammetry, POWER density, ZINC electrodes

Abstract

Incorporating metal compound nanoparticles in carbonaceous matrix is a valid strategy to fabricate highly efficient oxygen reduction electrocatalysts. Herein, N, P-codoped carbon nanotubes embedded with Fe2P nanoparticles (Fe2P/NPCt) were synthesized in this work. Results show carbon nanotubes have a large specific surface area (987 m² g−1 ) with an inner diameter of ∼60 nm. About 5.90 wt% nitrogen (35.18% pyridinic N) and 2.56 wt% phosphorus (mainly in the form of P–C and P–Fe) was doped in Fe2P/NPCt. HRTEM and XRD results confirmed the well dispersed Fe2P nanoparticles in 5 ∼10 nm on carbon nanotubes. The electrochemical performance of Fe2P/NPCt was evaluated in 0.10 M KOH using cyclic voltammetry, linear scanning voltammetry, and chronoamperometry. Fe2P/NPCt exhibits high electrocatalytic activity towards oxygen reduction with an onset potential of 1.029 V (vs RHE) and a limited current density of 6.79 mA cm−2, surpassing those of 20% Pt/C (0.950 V and 5.20 mA cm−2 ). Furthermore, Fe2P/NPCt presents outstanding durability and good methanol tolerance during long-term ORR. When assembled in a primary zinc-air battery (ZAB), the maximum power density and specific capacity of ZAB reach 175.48 mW cm−2 and 744.1 mAh g−1, respectively, outperforming ZAB equipped with 20% Pt/C. [ABSTRACT FROM AUTHOR]

Published

2022

2. PVP-Assisted Iron-Doped ZIF-8 as an Efficient Fe-N-C Oxygen Reduction Electrocatalyst for Zinc-Air Batteries.

Author

Ruixiang Wang, Yanyang Wang, Zheqin Chen, XiaoCong Zhong, Yongmin Xie, Xiaobo Ji, Jiaming Liu, Shubiao Xia, and Zhifeng Xu

Subjects

OXYGEN reduction, DOPING agents (Chemistry), CARBON composites, ENERGY conversion, POTENTIAL energy, STORAGE batteries, HYDROGEN evolution reactions, OXYGEN

Abstract

Transition metal/nitrogen carbon composite (M/NC) is a highly active oxygen reduction reaction (ORR) electrocatalyst, widely used in fuel cells and zinc-air batteries. Herein, a uniform and regular PVP-assisted iron-doped nano dodecahedron (ZP0.1F/NC) is prepared by a simple and efficient one-step in-solution reaction, followed by controlled in situ pyrolysis. The synthesized electrocatalyst showed excellent electrocatalytic ORR activity in an alkaline medium. Compared with standard 20% Pt/C electrocatalyst, ZP0.1F/NC exhibited onset potential (Eonset) (0.974 V vs 0.967 V), half-wave potential (E1/2) (0.861 V vs 0.857 V) and the limiting current density (jd) was 6.373 mA cm−2 vs 5.401 mA cm−2, also better than the Fe doped ZIF-8 nitrogen composite (ZF/NC), PVP auxiliary ZIF-8 (ZP0.1/NC) and pure ZIF-8 nitrogen composite (Z/NC) synthesized by the same procedure. In addition, the zinc-air battery assembled with ZP0.1F/NC also exhibits outstanding discharge capacity, with a specific capacity and energy density of 793.3 mAh g−1 and 974.9 Wh kgZn-1 respectively, much higher than that of commercial 20% Pt/C based zinc-air battery (719.8 mAh g−1, 842.6 Wh kgZn-1 ), indicating its great potential in practical energy conversion and storage. [ABSTRACT FROM AUTHOR]

Published

2022

3. Study on Reservoir Optimal Operation in Heavy Sediment-laden Rivers

Author

Huang Jianhong, Zhifeng Xu, and Youli Zhang

Subjects

Hydrology, Environmental science, Sediment

Abstract

The rivers in northern China have less water and more sediment, and the amount of incoming sediment is mainly concentrated in the flood season. In order to reduce the sediment deposition in reservoirs, study on reservoir optimized operation needs to be carried out. Traditional reservoir operation usually adopts a single normal pool level and a single flood control level, which does not take into account changes of the reservoir storage capacity with time. Due to the large capacity of the reservoir in the early stage of operation, the lower normal pool level can also meet the water supply demand. Therefore, it is possible to reduce the normal pool level and the flood control level. Reservoir capacity decreases in the later stages of reservoir operation. Increasing the normal pool level and the flood control level can increase the storage capacity. This paper uses a mathematical model to simulate the remaining capacity of the reservoir under different control operating levels. The results show that scheme 4 has the best results.

Published

2020

4. Study on Reservoir Optimal Operation in Heavy Sediment-laden Rivers.

Author

Zhifeng Xu, Jianhong Huang, and Youli Zhang

Published

2020