Email this article The synthesis, structure, and electrochemical properties of Li2FeSiO4-based lithium-accumulating electrode material
- Authors: Ivanishchev A.V.1,2, Churikov A.V.2, Akmaev A.S.2, Ushakov A.V.2, Ivanishcheva I.A.2, Gamayunova I.M.2, Sneha M.J.3, Dixit A.3
-
Affiliations:
- Center for Electrochemical Energy Storage
- Institute of Chemistry
- Department of Physics and Center for Solar Energy
- Issue: Vol 53, No 3 (2017)
- Pages: 302-311
- Section: Article
- URL: https://journal-vniispk.ru/1023-1935/article/view/188567
- DOI: https://doi.org/10.1134/S1023193517030089
- ID: 188567
Cite item
Open Access
Access granted
Subscription Access
Abstract
Different approaches to synthesis of Li2FeSiO4-based electrode materials for lithium intercalation, using low-cost and abundant Li-, Si-, and Fe-containing parent substances, are discussed. XRD, SEM, and a laser-diffraction analyzer of particle size were used for structure and morphology characterization of the composite electrode materials. Li2FeSiO4 was shown to be the main lithium-accumulating crystalline phase; minor LiFeO2 and Li2SiO3 admixtures are also present. The material microparticles’ average size was shown to vary from tenths of micrometer to 1 μm. Larger objects sized ca. 2–4 μm are the microparticles’ agglomerates. The material electrochemical properties were studied by dc chronopotentiometry (galvanostatic charging–discharging) and cyclic voltammetry with potential linear sweeping. The initial reversible cycled capacity of the best samples is 170 mA h/g. The anodic and cathodic processes manifest obvious hysteresis caused by the presence of several different lithium ion energy states in the material; the transition between the states is kinetically hindered. The dependences of the specific capacity and its stability under cycling on the current load and the conductive carbon component content in the composite were elucidated.
About the authors
A. V. Ivanishchev
Center for Electrochemical Energy Storage; Institute of Chemistry
Author for correspondence.
Email: ivanischevav@inbox.ru
Russian Federation, Nobel str. 3, Moscow, 143026; Astrakhanskaya str. 83, Saratov, 410012
A. V. Churikov
Institute of Chemistry
Email: ivanischevav@inbox.ru
Russian Federation, Astrakhanskaya str. 83, Saratov, 410012
A. S. Akmaev
Institute of Chemistry
Email: ivanischevav@inbox.ru
Russian Federation, Astrakhanskaya str. 83, Saratov, 410012
A. V. Ushakov
Institute of Chemistry
Email: ivanischevav@inbox.ru
Russian Federation, Astrakhanskaya str. 83, Saratov, 410012
I. A. Ivanishcheva
Institute of Chemistry
Email: ivanischevav@inbox.ru
Russian Federation, Astrakhanskaya str. 83, Saratov, 410012
I. M. Gamayunova
Institute of Chemistry
Email: ivanischevav@inbox.ru
Russian Federation, Astrakhanskaya str. 83, Saratov, 410012
M. J. Sneha
Department of Physics and Center for Solar Energy
Email: ivanischevav@inbox.ru
India, Radjastan, 342011
A. Dixit
Department of Physics and Center for Solar Energy
Email: ivanischevav@inbox.ru
India, Radjastan, 342011
Supplementary files
