Tailored Redox Kinetics, Electronic Structures and Electrode/Electrolyte Interfaces for Fast and High Energy‐Density Potassium‐Organic Battery

et al. 2020

Trans. Tianjin Univ.

The demands for high-performance and low-cost batteries make K-ion batteries (KIBs) considered as promising supplements or alternatives for Li-ion batteries (LIBs). Nevertheless, there are only a small amount of conventional inorganic electrode materials that can be used in KIBs, due to the large radius of K+ ions. Differently, organic electrode materials (OEMs) generally own sufficiently interstitial space and good structure flexibility, which can maintain superior performance in K-ion systems. Therefore, in recent years, more and more investigations have been focused on OEMs for KIBs. This review will comprehensively cover the researches on OEMs in KIBs in order to accelerate the research and development of KIBs. The reaction mechanism, electrochemical behavior, etc., of OEMs will all be summarized in detail and deeply. Emphasis is placed to overview the performance improvement strategies of OEMs and the characteristic superiority of OEMs in KIBs compared with LIBs and Na-ion batteries.

Section: Aromatic Imidesmentioning

confidence: 95%

Organic Electrode Materials for Non-aqueous K-Ion Batteries

Wang

Lü

et al. 2020

Trans. Tianjin Univ.

“…In comparison, for the concentrated electrolyte systems, the decrease of the LUMO energy levels of anions caused by its interaction with K + ions leads to a preferen tial anion reduction reaction. [32,104,107,171] For example, a thinner anionderived SEI layer was formed in the electrolyte of 2.5 m KPF 6 /DEGDME compared with that in 1 m KPF 6 /DEGDME, thus enhanced performance was achieved on KVOPO 4 and K 1.69 Mn[Fe(CN) 6 ] 0.85 •4H 2 O cathodes. [171] Also the KTFSIbased concentrated electrolytes, such as 5 m KTFSI/DEGDME, 5 m KTFSI/DME and 4 m KTFSI/EC:DEC, allow more TFSIions to reach the interface and can introduce a more compact and thinner SEI layer with a larger amount of inorganic spe cies.…”

Section: Concentration Dependency Of Sei Layermentioning

confidence: 99%

Electrolytes and Interphases in Potassium Ion Batteries

et al. 2021

Potassium ion batteries (PIBs) are recognized as one promising candidate for future energy storage devices due to their merits of cost‐effectiveness, high‐voltage, and high‐power operation. Many efforts have been devoted to the development of electrode materials and the progress has been well summarized in recent review papers. However, in addition to electrode materials, electrolytes also play a key role in determining the cell performance. Here, the research progress of electrolytes in PIBs is summarized, including organic liquid electrolytes, ionic liquid electrolytes, solid‐state electrolytes and aqueous electrolytes, and the engineering of the electrode/electrolyte interfaces is also thoroughly discussed. This Progress Report provides a comprehensive guidance on the design of electrolyte systems for development of high performance PIBs.

“…Although redox kinetics have a significant impact on rate performance, the related research is rare: to date, only one research report by Tong [31] et al is available. They could easily adjust the electrochemical performance and redox kinetics of PTCDA‐based polymers (PTCDA‐ k C ( k =0, 2, 3, 4), 25 , Figure 11) by changing the length of the alkyl chain.…”

Section: Polymersmentioning

confidence: 99%

Organic Materials as Electrodes in Potassium‐Ion Batteries

Huang

2021

Chemistry A European J

The integrated advantages of organic electrode materials and potassium metal make the organic potassium‐ion batteries (OPIBs) promising secondary batteries. This review summarizes the latest research progress on OPIBs according to the different types of electrode materials (namely, organic small molecules compounds, polymers, and frameworks (metal–organic frameworks (MOFs), covalent organic frameworks (COFs)). Additionally, the research prospects and outlook for OPIBs are also provided.