registered   |   log in
  中文

mxene academic

 
contact us

hotline:

17715390137

Tel/Wechat:

  18101240246 (Technology)

0512-68565571

Emailmxenes@163.com (Sales Engineer)bkxc.bonnie@gmail.com

Scan the code to follow or search the official account on WeChat: 

2D Materials Fronrier After paying attention, 

click on the lower right corner to contact us, 

Enter enterprise WeChat.

Professional Services Online

mxene academic
position: home > mxene academic > mxene energy storage

ACS Energy Letters: High-Quality Supported Porous MXene Films for Pseudocapacitors

source:beike new material Views:2629time:2022-07-19 QQ Academic Group: 1092348845

已传文件:photo/1631586161.png North Konami can provide MXene (can be customized)

     Mass production of ordered and porous three-dimensional (3D) electrodes is an important prerequisite for the realization of practical energy storage devices. MXenes have attracted extensive attention due to their excellent electrical conductivity and surface redox reactions; however, MXenes face challenges in realizing three-dimensional porous structures, especially under conditions of large mass loading.

      Recently, Professor Bo Zheng of Zhejiang University published a research paper titled: High-Mass-Loading Porous Ti3C2Tx Films for Ultrahigh-Rate Pseudocapacitors in the well-known academic journal ACS Energy Letters. In this paper, a three-dimensional high-rate capacitive electrode with high application value is designed and synthesized.

Figure 1. Principles of SEM and RRFCA.

Figure 2. XPS FTIR and surface zeta potential characterization.

Figure 3. Comparative test of electrochemical performance.

Figure 4. Electrochemical performance test of porous MXene membrane.

   This paper describes the use of a facile RRFCA (reduced-repulsion freeze-casting assembly) method for MXenes to fabricate 3D porous pseudocapacitor electrodes. By adding KOH solution to the MXene suspension, the problem of difficult lyophilization assembly caused by electrostatic repulsion between sheets is solved. The surface of Ti3C2Tx was modified with less electronegative hydroxyl groups, which enhanced the interlayer bonding.

Literature link:

https://doi.org/10.1021/acsenergylett.0c00704


 

Reminder: Beijing Beike New Material Technology Co., Ltd. supplies products only for scientific research, not for humans
All rights reserved © 2019 beijing beike new material Technology Co., Ltd 京ICP备16054715-2号
advisory
phone
Email:mxenes@163.com
Tel:+86-17715390137
scan

scan
WeChat