Design and comparative analysis of aluminum-BiFeO3-based plasmonic device in the near-infrared region

S. Shukla, P. Raghunath, S. Mehta, P. Arora
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Abstract

In this work, a nano-plasmonic device based on Aluminum with BiFeO3 (BFO), as a multiferroic oxide with remarkable dielectric properties, is engineered using the transfer matrix method for implementation in an optical communication band for sensing applications. A comparative study is performed between different dielectric materials (e.g., BFO, Silicon, and Indium Phosphide), and the highest Figure of Merit (FOM) is achieved for the surface plasmon resonance sensor with BFO as the intermediate layer. To further increase the binding efficiency of the biomolecules with the sensing surface, a monolayer of 2D nanomaterial, namely Molybdenum disulfide, Graphene, MXene, and Fluorinated Graphene (FG), is added to the surface of the plasmonic device. After a rigorous analysis, FG is found to have the highest FOM of 334°/RIU and sensitivity of 125°/RIU. In summary, our work reveals potential applications for the proposed nano-plasmonic device based on Al-BFO configuration as a new type of supporting material with a monolayer of FG for enhancing biosensing activity.

Abstract Image

基于铝-BiFeO3 的近红外区等离子器件的设计与比较分析
在这项研究中,利用转移矩阵法设计了一种基于铝与 BiFeO3(BFO)的纳米等离子器件,BFO 是一种多铁性氧化物,具有显著的介电特性,可用于光通信波段的传感应用。对不同介电材料(如 BFO、硅和磷化铟)进行了比较研究,结果表明以 BFO 为中间层的表面等离子体共振传感器具有最高的优越性(FOM)。为了进一步提高生物分子与传感表面的结合效率,在质子器件表面添加了单层二维纳米材料,即二硫化钼、石墨烯、MXene 和氟化石墨烯(FG)。经过严格分析后发现,FG 具有最高的 FOM(334°/RIU)和灵敏度(125°/RIU)。总之,我们的工作揭示了基于 Al-BFO 配置的拟议纳米等离子体器件的潜在应用,该器件是一种带有单层 FG 的新型支撑材料,可增强生物传感活性。
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