Investigation of electronic structure and electrochemical properties of Na2MnSiO4 as a cathode material for Na-ion batteries

TL;DR

This study uses first principles calculations to analyze the electronic structure and electrochemical properties of Na2MnSiO4, revealing its potential as a high-voltage cathode material for Na-ion batteries with insights into Na diffusion and redox mechanisms.

Contribution

It provides a comprehensive thermodynamic and electronic analysis of Na2MnSiO4, including voltage profile, phase behavior, bonding interactions, and effects of Mn-site substitution, which were not previously detailed.

Findings

Average voltage of 4.2 V for Na2MnSiO4

Two-phase mixing occurs beyond 1.5 Na/f.u.

Mn-O interaction is iono-covalent, Si-O is covalent

Abstract

The polyanionic compound Na2MnSiO4 is regarded as one of the promising cathode materials for Na-ion batteries due to good specific capacity with its attractive prospect of utilization of two electrons in the redox processes. So, in this study, we have performed the thermodynamic and electronic structure analysis of Na2MnSiO4 using first principles density functional theory calculations. The intermediate ground state configurations for Na2MnSiO4of Na de-intercalation were found using the cluster expansion method and are used to obtain the 0 K voltage profile as a function of Na concentration. This material shows an average voltage of 4.2 V and the finite temperature analysis at 300 K using Monte Carlo simulations indicates that this material undergoes two phase mixing when desodiate beyond 1.5 Na/f.u. The chemical bonding interactions between the constituents are analyzed using the density of states, crystal orbital Hamilton population, charge density, charge transfer and electron localization function analyses. From these analyses we found that the interaction between Mn and O is iono-covalent and that between Si-O is mainly covalent in nature. The involvement of oxygen in the redox reaction apart from the transition metal is identified using the Bader charge analysis. Relevant Na diffusion pathways and their corresponding calculated energy barriers are compared with the partially Fe substituted Na2MnSiO4 to understand the effect of Mn-site substitution on the process of Na migration through this material.