MIM Waveguide Based Multi-Functional Plasmonic Logic Device by Phase Modulation

IF 2.1 4区 工程技术 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC
Lokendra Singh;Prakash Pareek;Chinmoy Saha;Vigneswaran Dharsthanan;Niteshkumar Agrawal;Roshan Kumar
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Abstract

Energy consumption is a primary concern in the computational process of heavy networks like Google, etc., where the key goal is to make them ultra-fast with low heat generation. Optical processing can play an important role in shrinking the heat energy and allow the system to work smoothly but beyond the Boltzmann limit of kTLn2. In the current epoch, optical reversible logic functions are greatly considered as a potential solution for minimizing heat dissipation or information loss and found applications in nanotechnology, logic circuits for biomedical applications, and so on. This work proposed the optical Kerr effect-based multifunctional plasmonic logic device. The Kerr effect provides switching of optical signal across the output ports of the Mach-Zehnder interferometer (MZI) with a high extinctionratio (ER). The intensity of the input signal is defined as different states of input logic. In addition, the presence and absence of an optical signal at output ports are used to set logic ‘1’ and ‘0’, respectively. Finally, four different logic functions including reversible Toffoli gate (TG), half adder (HA), NOR and XOR gate are realized through the proposed device. The device is analyzed through the finite difference time domain method in Opti-FDTD. Further, the analysis of basic elements is done in terms of ER, insertion loss (IL), and transmission efficiency.
通过相位调制实现基于 MIM 波导的多功能等离子体逻辑器件
在谷歌等重型网络的计算过程中,能耗是一个首要问题,其关键目标是使其具有超快速度和低发热量。光学处理可以在减少热能方面发挥重要作用,让系统平稳工作,但要超过 kTLn2 的玻尔兹曼极限。在当今时代,光学可逆逻辑功能被认为是最大限度减少散热或信息损失的潜在解决方案,并在纳米技术、生物医学应用的逻辑电路等领域得到了应用。这项工作提出了基于光学克尔效应的多功能质子逻辑器件。克尔效应可在高消光比(ER)的马赫-泽恩德干涉仪(MZI)输出端口上切换光信号。输入信号的强度被定义为输入逻辑的不同状态。此外,输出端口光信号的存在和不存在也分别用于设置逻辑 "1 "和 "0"。最后,该器件实现了四种不同的逻辑功能,包括可逆托福利门(TG)、半加法器(HA)、NOR 门和 XOR 门。该器件通过 Opti-FDTD 中的有限差分时域法进行分析。此外,还根据 ER、插入损耗 (IL) 和传输效率对基本元件进行了分析。
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来源期刊
IEEE Transactions on Nanotechnology
IEEE Transactions on Nanotechnology 工程技术-材料科学:综合
CiteScore
4.80
自引率
8.30%
发文量
74
审稿时长
8.3 months
期刊介绍: The IEEE Transactions on Nanotechnology is devoted to the publication of manuscripts of archival value in the general area of nanotechnology, which is rapidly emerging as one of the fastest growing and most promising new technological developments for the next generation and beyond.
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