Nanoelectronics Devices: Design, Materials, and Applications (Part I)

Author(s): Vandana Devi Wangkheirakpam*, Brinda Bhowmick, Puspa Devi Pukhrambam and Ghanshyam Singh

DOI: 10.2174/9789815136623123010012

Optically Gated Vertical Tunnel FET for Near-Infrared Sensing Application

Pp: 237-255 (19)

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Nanoelectronics Devices: Design, Materials, and Applications (Part I)

Optically Gated Vertical Tunnel FET for Near-Infrared Sensing Application

Author(s): Vandana Devi Wangkheirakpam*, Brinda Bhowmick, Puspa Devi Pukhrambam and Ghanshyam Singh

Pp: 237-255 (19)

DOI: 10.2174/9789815136623123010012

* (Excluding Mailing and Handling)

Abstract

This chapter presents a vertical tunnel FET (VTFET) designed for light sensing application to use in medical diagnosis and treatment, tracking of targets, analysis of the chemical composition, surveillance cameras, etc. Various aspects related to this optimized VTFET photosensor are analyzed to benchmark its performance among those available in the literature. A brief discussion on the conventional TFET geometry is presented to give a better understanding of the advantages of its working methodologies. The concept of sensing using optically gated VTFET is studied with a remarkable focus on design perspective and detection principle. The modified TFET geometry has a photosensitive gate called an optically gated VTFET to use in near-infrared sensing applications. The design approach based on Synopsys Technology Computer-Aided Design (TCAD), along with suitable physics-based models of simulation, is introduced in this chapter. A wavelength range of 0.7µm to 1µm is considered in the simulation process. Analyses of different sensing parameters, such as sensitivity, responsivity, etc., at low intensity of illumination, are brought to light with the main focus on the viability of the proposed sensor to be a superior one. Through such analysis, this chapter presents a low-power, highly sensitive, cost-effective, faster response time photodetector that may be applicable for next-generation photosensors.