Design and Performance Analysis of Tunnel Field Effect Transistor With Buried Strained Si1− x Ge x Source Structure Based Biosensor for Sensitivity Enhancement

Design and Performance Analysis of Tunnel Field Effect Transistor With Buried Strained Si1− x Ge x Source Structure Based Biosensor for Sensitivity Enhancement

In this paper, a dielectrically modulated symmetrical double gate, having dual gate material, Tunnel Field-Effect transistor with Buried strained Si1- x Ge x source structure, has been investigated as a biosensor. This structure is proposed for the very first time to electrically detect the biologic...

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Bibliographic Details
Published in:IEEE sensors journal Vol. 20; no. 22; p. 13178
Main Authors: Aadil Anam, Anand, Sunny, Amin, S Intekhab
Format: Journal Article
Language:English
Published: New York The Institute of Electrical and Electronics Engineers, Inc. (IEEE) 01-01-2020
Subjects:
Biomolecules
Biosensors
Buried structures
Field effect transistors
Germanium
Optimization
Power consumption
Semiconductor devices
Sensitivity enhancement
Silicon
Steric hindrance
Transistors
Work functions
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Summary:In this paper, a dielectrically modulated symmetrical double gate, having dual gate material, Tunnel Field-Effect transistor with Buried strained Si1- x Ge x source structure, has been investigated as a biosensor. This structure is proposed for the very first time to electrically detect the biological molecules at very low power consumption. In the proposed biosensor structure, the top thin Si channel of TFET is overlapped with the Si1- x Ge x source. This increases the tunneling area, due to which ON current of the biosensor also increases. To detect the biomolecules a nanogap cavity has been created over 1nm gate oxide. Also to decrease the short channel effects, dual-gate material with different metal work functions is used on both the symmetrical double gates. By varying the small bandgap material (Ge) mole fraction in the SiGe and after inserting different biological molecules (of the different dielectric) in a cavity, the variation in transfer characteristic, [Formula Omitted] current ratio, SS along with their sensitivity is studied. Also, to signify the presence of biomolecules in the cavity, the [Formula Omitted] ratio as a sensing metric is studied under the sub-threshold region. Along with the fully filled biomolecules cavity, the partially filled cavity and the effect of a steric hindrance have also investigated in this paper with various non-uniform step patterns of biomolecules in the cavity. Because, in a more practical situation, the steric hindrance effect doesn’t allow the cavity to be entirely filled. Also, this paper addresses the optimization of drain current sensitivity, by different cavity length with different source overlapping cavity.
ISSN:1530-437X
1558-1748
DOI:10.1109/JSEN.2020.3004050