Density Functional Theory Analysis of the Impact of Boron Concentration and Surface Oxidation in Boron-Doped Graphene for Sodium and Aluminum Storage

C Pub Date : 2023-09-28 DOI:10.3390/c9040092
Milica S. Ritopečki, Natalia V. Skorodumova, Ana S. Dobrota, Igor A. Pašti
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Abstract

Graphene is thought to be a promising material for many applications. However, pristine graphene is not suitable for most electrochemical devices, where defect engineering is crucial for its performance. We demonstrate how the boron doping of graphene can alter its reactivity, electrical conductivity and potential application for sodium and aluminum storage, with an emphasis on novel metal-ion batteries. Using Density Functional Theory calculations, we investigate both the influence of boron concentration and the oxidation of the material on the mentioned properties. It is demonstrated that the presence of boron in graphene increases its reactivity towards atomic hydrogen and oxygen-containing species; in other words, it makes B-doped graphene more prone to oxidation. Additionally, the presence of these surface functional groups significantly alters the type and strength of the interaction of Na and Al with the given materials. Boron-doping and the oxidation of graphene is found to increase the Na storage capacity of graphene by a factor of up to four, and the calculated sodiation potentials indicate the possibility of using these materials as electrode materials in high-voltage Na-ion batteries.
硼掺杂石墨烯中硼浓度和表面氧化对钠和铝存储影响的密度泛函理论分析
石墨烯被认为是一种应用前景广阔的材料。然而,原始石墨烯并不适用于大多数电化学器件,其中缺陷工程对其性能至关重要。我们展示了石墨烯的硼掺杂如何改变其反应性、导电性以及在钠和铝存储方面的潜在应用,重点是新型金属离子电池。利用密度泛函理论计算,我们研究了硼浓度和材料氧化对上述性能的影响。结果表明,石墨烯中硼的存在增加了其对原子氢和含氧物质的反应性;换句话说,它使掺杂b的石墨烯更容易氧化。此外,这些表面官能团的存在显著地改变了Na和Al与给定材料相互作用的类型和强度。硼掺杂和石墨烯氧化可使石墨烯的钠存储容量增加4倍,计算出的钠化电位表明,这些材料有可能用作高压钠离子电池的电极材料。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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