Design of Charge-Plasma-based Cylindrical-Gate-Nanowire TFET with low power and enhanced sensitivity for bio-sensing

This paper proposes a Charge-Plasma-based Cylindrical-Gate-Nanowire Tunnel Field Effect Transistor (CPCG-NWTFET) and High-k Gate Stack Charge-Plasma-based Cylindrical-Gate-Nanowire Tunnel Field Effect Transistor (HKGS-CPCG-NWTFET) with the dielectric modulated split-gate label-free biosensor. Charge...

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Bibliographic Details
Published in:Applied physics. A, Materials science & processing Materials science & processing, 2021-05, Vol.127 (5), Article 347
Main Authors: Singh, Navaneet Kumar, Mandal, Durbadal, Kar, Rajib
Format: Article
Language:English
Subjects:
Applied physics
Biomolecules
Biosensors
Characterization and Evaluation of Materials
Condensed Matter Physics
Cylindrical plasmas
Field effect transistors
Machines
Manufacturing
Materials science
Mathematical analysis
Nanotechnology
Nanowires
Optical and Electronic Materials
Parameter sensitivity
Permittivity
Physics
Physics and Astronomy
Plasma
Processes
Semiconductor devices
Sensitivity enhancement
Surfaces and Interfaces
Thin Films
Threshold voltage
Transistors
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Summary:This paper proposes a Charge-Plasma-based Cylindrical-Gate-Nanowire Tunnel Field Effect Transistor (CPCG-NWTFET) and High-k Gate Stack Charge-Plasma-based Cylindrical-Gate-Nanowire Tunnel Field Effect Transistor (HKGS-CPCG-NWTFET) with the dielectric modulated split-gate label-free biosensor. Charged and uncharged (neutral) biomolecules with the different values of dielectric constants (K) are considered as sensing elements. As the biomolecules are introduced in the cavity, the value of the dielectric constant in the cavity is changed, which in turn changes the OFF-current, ON-current and threshold voltage ( V th ) which are considered as the sensitivity parameters for sensing the biomolecules. The technique used in designing of cylindrical-gate-nanowire TFET-based biosensor is charged plasma. Various fill factors, e.g. 12%, 26%, 42%, 59%, 79% and 100% are used to observe its effect on the sensitivity. The proposed CPCG-NWTFET structure shows enhanced characteristics in many respects. The subthreshold slope (SS) is improved with fill factor and high dielectric constant. The sensitivity of the CPCG-NWTFET biosensor is high as compared to HKGS-CPCG-NWTFET. Maximum sensitivity enhancement calculated with the positive and negative charge of biomolecules with respect to S ON and S OFF for CPCG-NWTFET is 13.8%, 14.2% and 23,337.2%, 538.1%, respectively. Similarly, maximum sensitivity enhancement with respect to S OFF for CPCG-NWTFET with fill factors (FF) is 13953.2%, whereas the sensitivity with respect to S ON is higher for HKGS-CPCG-NWTFET. Thus, CPCG-NWTFET is a strong candidate for charge-plasma-based biosensor with low power and enhanced sensitivity.
ISSN:0947-8396
1432-0630
DOI:10.1007/s00339-021-04495-9