文章信息/Info

Title:

Preparation and Application in the Field of Electricity Catalysis and Energy Storage of Antimonene

文章編號:

1674-3962(2022)11-0909-12

作者:

雷雪顏1; 2; 傅正平1; 2; 陸亞林1; 2; 向斌1; 2

(1.中國科學技術大學材料科學與工程系 中國科學院能量轉換材料重點實驗室，安徽 合肥 230026) (2.先進光子科學與技術安徽省實驗室 合肥微尺度物質科學國家研究中心，安徽 合肥 230026)

Author(s):

LEI Xueyan1; 2; FU Zhengping1; 2; LU Yalin1; 2; XIANG Bin1; 2

(1. CAS Key Laboratory of Materials for Energy Conversion, Department of Materials Science & Engineering, University of Science and Technology of China, Hefei 230026, China) (2. Hefei National Laboratory for Physical Sciences at the Microscale， Anhui Laboratory of Advanced Photon Science and Technology, Hefei 230026, China)

關鍵詞:

銻烯; 制備方法; 電催化; 儲能; 鋰離子電池; 鈉離子電池; 超級電容器

Keywords:

antimonene;  preparation method;  electrocatalysis;  energy storage; lithium ion battery;  sodium ions battery;  supercapacitor

分類號:

O614.5；TM912；TQ152

DOI:

10.7502/j.issn.1674-3962.202105020

文獻標志碼:

A

摘要:

2015年首次報道的銻烯，作為一種新型的2D材料，因具有獨特的光電特性、皺片狀的結構、大的層間通道尺寸、快速的離子擴散性能和良好的環境穩定性，引起了科學界的廣泛關注，其制備方法和實際應用在近幾年一直是國內外的研究熱點。在實際應用中，高質量銻烯的制備方法是實現銻烯獨特性能的關鍵。為了更好地制備銻稀以及利用其性質，詳細介紹了近幾年報道的銻烯的制備方法，包括機械剝離法、液相剝離法、電化學剝離法、濕化學法、外延法及其它方法，概述了銻烯在電催化和儲能領域的應用研究現狀，并進行了總結與展望，同時對銻烯應用于超級電容器時存在的問題進行了詳細的分析，為銻烯在超級電容器領域的進一步探索提供了思路;有利于研究者快速了解和掌握銻烯不同的制備方法以及在電催化和儲能領域的應用研究進展，為研究者理解和利用銻烯的獨特性質提供參考。

Abstract:

As a new type of two-dimensional material, antimonene, which was first reported in 2015, has attracted widely attention from scientific community because of the unique optical properties, crumpled structure, large interlamellar channel size, fast ion diffusion performance, and excellent environmental stability. Its preparation method and application has been an international hot research topic in recent years. In practical application, the design of preparation method of high quality antimonene is the key to realize its unique performance. To better prepare antimonene and use its properties, in this paper, the preparation methods for antimonene reported in recent years are introduced in detail, including mechanical stripping method, liquid phase stripping method, electrochemical stripping method, wet chemical method, epitaxy method, and other methods. The application of antimonene in the fields of electrocatalysis and energy storage are introduced in detail. And the corresponding summary and prospect are discussed. The problems existing in the application of antimonene in supercapacitors are analyzed in detail, which provides ideas for the further exploration of antimonene in supercapacitors. This paper is helpful for researchers to quickly understand and master the different preparation methods of antimonene and its application in the fields of electrocatalysis and energy storage, and provides a reference for researchers to understand and utilize the unique properties of antimonene.