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Battery Energy Materials: Theory Development and Applications

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Dr. Hena Das

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Laboratory for Materials and Structures, WRHI, Institute of Innovative Research, Tokyo Institute of Technology, 4259 Nagatsuta, Midori-ku, Yokohama 226-8503, Japan
Interests: quantum mechanical modeling; magnetic and magnetoelectric materials; ferroelectrics; topological phases; energy materials; spintronics; complex oxides

Special Issue Information

Dear Colleagues,

Theoretical investigations, in tandem with laboratory-based experimental work, have been steadily providing significant insights into the improvement in energy storage technologies. Thus, this Special Issue of the journal Energies, entitled Battery Energy Materials: Theory Development and Applications, aims to publish papers based on original theoretical investigations in the field of battery applications. We invite research works focusing on the (1) investigation of various phenomena of battery materials, such as phase stability and ionic transport; (2) design of new materials and the development of materials informatics; (3) understanding of surface and interface activities in batteries; and (4) development and application of advanced theoretical techniques, for publication in this Special Issue

Dr. Hena Das
Guest Editor

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Research

11 pages, 1839 KiB

Open AccessArticle

A New Graphitic Nitride and Reduced Graphene Oxide-Based Sulfur Cathode for High-Capacity Lithium-Sulfur Cells

by Artur M. Suzanowicz, Youngjin Lee, Hao Lin, Otavio J. J. Marques, Carlo U. Segre and Braja K. Mandal

Energies 2022, 15(3), 702; https://doi.org/10.3390/en15030702 - 19 Jan 2022

Cited by 2 | Viewed by 2341

Abstract

Lithium-sulfur (Li-S) batteries can provide at least three times higher energy density than lithium-ion (Li-Ion) batteries. However, Li-S batteries suffer from a phenomenon called the polysulfide shuttle (PSS) that prevents the commercialization of these batteries. The PSS has several undesirable effects, such as depletion of active materials from the cathode, deleterious reactions between the lithium anode and electrolyte soluble lithium polysulfides, resulting in unfavorable coulombic efficiency, and poor cycle life of the battery. In this study, a new sulfur cathode composed of graphitic nitride as the polysulfide absorbing material and reduced graphene oxide as the conductive carbon host has been synthesized to rectify the problems associated with the PSS effect. This composite cathode design effectively retains lithium polysulfide intermediates within the cathode structure. The S@RGO/GN cathode displayed excellent capacity retention compared to similar RGO-based sulfur cathodes published by other groups by delivering an initial specific capacity of 1415 mA h g⁻¹ at 0.2 C. In addition, the long-term cycling stability was outstanding (capacity decay at the rate of only 0.2% per cycle after 150 cycles). Full article

(This article belongs to the Special Issue Battery Energy Materials: Theory Development and Applications)

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10 pages, 3147 KiB

Open AccessArticle

Electrochemical Properties of Pristine and Vanadium Doped LiFePO₄ Nanocrystallized Glasses

by Justyna E. Frąckiewicz, Tomasz K. Pietrzak, Maciej Boczar, Dominika A. Buchberger, Marek Wasiucionek, Andrzej Czerwiński and Jerzy E. Garbarczyk

Energies 2021, 14(23), 8042; https://doi.org/10.3390/en14238042 - 1 Dec 2021

Cited by 6 | Viewed by 1800

Abstract

In our recent papers, it was shown that the thermal nanocrystallization of glassy analogs of selected cathode materials led to a substantial increase in electrical conductivity. The advantage of this technique is the lack of carbon additive during synthesis. In this paper, the electrochemical performance of nanocrystalline LiFePO₄ (LFP) and LiFe_0.88V_0.08PO₄ (LFVP) cathode materials was studied and compared with commercially purchased high-performance LiFePO₄ (C-LFP). The structure of the nanocrystalline materials was confirmed using X-ray diffractometry. The laboratory cells were tested at a wide variety of loads ranging from 0.1 to 3 C-rate. Their performance is discussed with reference to their microstructure and electrical conductivity. LFP exhibited a modest electrochemical performance, while the gravimetric capacity of LFVP reached ca. 100 mAh/g. This value is lower than the theoretical capacity, probably due to the residual glassy matrix in which the nanocrystallites are embedded, and thus does not play a significant role in the electrochemistry of the material. The relative capacity fade at high loads was, however, comparable to that of the commercially purchased high-performance LFP. Further optimization of the crystallites-to-matrix ratio could possibly result in further improvement of the electrochemical performance of nanocrystallized LFVP glasses. Full article

(This article belongs to the Special Issue Battery Energy Materials: Theory Development and Applications)

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