Design, Preparation and Electrochemical Performance Regulation of Electrode Material for High Specific Capacity Lithium Ion Batteries
Abstract
In order to improve the preparation and regulation ability of high specific capacity lithium ion battery electrode material, a direct functionalization
control model based on an inert C-C bond is proposed for the electrochemical performance regulation of high specific capacity lithium ion battery
electrode material. The control model of a carbonyl allylation reaction of high specific capacity lithium ion battery electrode material and the
electrochemical reaction control model of high specific capacity lithium ion battery electrode material are constructed. Combined with the feedback
adjustment stability parameter adjustment method, the polar parameter in electrochemical regulation of battery electrode material is adjusted.
Combined with the fuzzy tracking identification method, the process of battery electrode material regulation is controlled. The heteroatom functional
groups are introduced to realize the steady-state regulation of the electrochemical performance of high specific capacity lithium ion battery electrode
material. The asymmetric carbonyl allylation reaction is used to regulate the molecular catalytic reaction during the preparation of the lithium ion
battery electrode material. The optimal controls of the design, preparation and electrochemical performance regulation of electrode material for high
specific capacity lithium ion batteries are realized. The results show that this method has a good steady-state and strong catalytic ability to regulate
the electrochemical performance of battery electrode material. The stability of electrochemical control is improved and the output gain of battery
electrode is higher.
Keywords: high specific capacity lithium ion; battery electrode material; electrochemical performance control; preparation
Cite As
K. Luo, B. Wei, "Design, Preparation and Electrochemical Performance Regulation of Electrode Material for High Specific
Capacity Lithium Ion Batteries", Engineering Intelligent Systems, vol. 29 no. 1, pp. 19-25, 2021.