A Comprehensive Review on Tunnel Field-Effect Transistor (TFET) Based Biosensors: Recent Advances and Future Prospects on Device Structure and Sensitivity

Reddy, N. Nagendra; Panda, Deepak Kumar

doi:10.1007/s12633-020-00657-1

Cited by 61 publications

(21 citation statements)

References 50 publications

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“…5a to Fig. 5f [35]. The surface of channel is applied with negative QF of −0.110 12 cm -2 , −0.510 12 cm -2 , and −110 12 cm -2 to mimic the different concentrations of target biomolecules [28].…”

Section: Application Of Interface Charge Densities For Difference Channel Widthsmentioning

confidence: 99%

“…These results show that all the simulated SiNW (InPNW) channel doping is affected by the application of different Q F values applied on them, hence indicate that the SiNW (InPNW) channel detect different target analyte concentrations that will be captured by the bioreceptor immobilized onto the device. The detection will be signified by the relative change in ID, which is the percentage difference of ID before and after detection [35]. InPNW -FET graph for biosensors at different channel doping of 0.1×10 14 cm -3 , 1×10 14 cm -3 , 10×10 14 cm -3 when applied with different Q F of −0.110 12 cm -2 , −0.510 12 cm -2 , and −1.010 12 cm -2 .…”

Section: Application Of Interface Charge Densities For Difference Channel Dopingmentioning

confidence: 99%

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Design and Simulation of InP and Silicon Nanowires With Different Channel Characteristic as Biosensors to Improve Output Sensitivity

nejad¹,

Tahi²,

Rezaie³

2021

Preprint

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This research contains a good comparison among technologies of SiNW-FET/InPNW-FET depending on the size of channel and dopants in channel for biosensing application based on the width and dopants for two types of silicon and InP materials in the nanowire channel. A device numerical modelling tool, Silvaco ATLAS is used in step one to design three p-type SiNW-FET/InPNW-FET biosensors with a channel width of 40 nm, 60 nm and 70 nm for these two types of materials and in step two to design three p-type SiNW-FET/InPNW-FET biosensors with different dopants of 0.1×1014 cm-3, 1×1014 cm-3 and 10×1014 cm-3 for these two types of materials. Their sensing process is depended on the alteration in charge density that causes changing in the electric field at the surface of the SiNW-FET/InPNW-FET. The resistivity of the device is changed when a negatively charged biomolecules species has a chemical reaction with the external surface of a P-type SiNW-FET/InPNW-FET. To investigate the effect of different channel width and dopants on the performance of the SiNW-FET/InPNW-FET biosensor, several negatively interface charge densities, QF (-0.1×1012 cm-2, -0.5×1012 cm-2, and -1×1012 cm-2) are introduced on the surface of the SiNW-FET/InPNW-FET channel to represent as the actual target analytics (DNA) captured by the bioreceptor of the biosensor. Based on the results, these negatively QF attract the hole carriers below the surface of p-type nanowire causes to collect carriers in the channel, and make an increase in the device output ID. Increase of the applied negative charge density has allowed for more ID to flow across the channel between drain and source region. The changes of ID with the applied QF are utilized to determine the sensitivities for all designed biosensor with different channel width and channel dopants. The minimum nanowire width of 40 nm with the minimum nanowire dopants of 0.1×1014 cm-3 for the high sensitivity silicon state of 3.6 μA/cm-2 compared to the indium phosphide state of 2.8 μA/cm-2. So the best performance for detecting the desired analyte in the silicon state with the lowest width and dopant to be seen.

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Section: Application Of Interface Charge Densities For Difference Channel Widthsmentioning

confidence: 99%

Section: Application Of Interface Charge Densities For Difference Channel Dopingmentioning

confidence: 99%

Design and Simulation of InP and Silicon Nanowires With Different Channel Characteristic as Biosensors to Improve Output Sensitivity

nejad¹,

Tahi²,

Rezaie³

2021

Preprint

View full text Add to dashboard Cite

show abstract

“…The conventional FET size is scaled down to improve the performance in terms of speed and power consumption but it is limited and restricted due to the encounter of the short channel effects (SECs) and high leakage current. The fundamental limitation on the minimum achievable subthreshold swing (SS > 60mv/dec) and the SCEs are treated as the major setback for the improvement of performance for the CFET‐based biosensors 11,12 …”

Section: Introductionmentioning

confidence: 99%

Performance analysis of Z‐shaped gate dielectric modulated (DM) tunnel field‐effect transistor‐(TFET) based biosensor with extended horizontal N+ pocket

Reddy

Panda

2021

Int J Numerical Modelling

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In this paper, a Z‐shaped gate dielectric modulated (DM) tunnel field‐effect transistor‐(TFET) based biosensor with extended horizontal n+ pocket in the source region is proposed and different performances were investigated. Effective structural modification has been done by considering the filed induced quantum confinements effects to enhance the various performances of the device in terms of ON current (Ion) and threshold voltage. The horizontal pocket beneath the source region of the ZHP‐DM‐TFET biosensor enables the vertical tunneling besides the lateral tunneling which leads to enhancement of device performance in terms of short channel effects, low OFF the current. A comparative study is also carried with existing biosensors and it is observed that the ZHP‐DM‐TFET biosensor shows superiority over the other biosensors due to its irregular arrangement of the gate and the horizontal n+ pocket provides. The sensitivity analysis of the device was further investigated by varying the dielectric constant of the biomolecules inside the nanocavity for the value from K = 1 to K = 10. The ZHP‐DM‐TFET biosensor shows a significant improvement in threshold voltage sensitivity 20% (k = 2), 35%(K = 4) and a 102 improvement in Ion/Ioff ratio. The impact of the thickness of the n+ pocket (pocket) over the sensitivity of the biosensor is also investigated.

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“…Many researchers were impressed and inspired by the FET-based biosensors' characteristics, carried out immense research, and reported a good and fruitful development in FET-based biosensors. The performance of the FET-based biosensors is high in class, but still, they are beyond touching the tip of the sensitivity because of the following hectic issues (1) the theoretical constraint on the minimum achievable subthreshold slope (SS > 60mv/dec) due to Boltzmann tyranny [KBT/q ln (10)] and (2) the short channel effects experience by the FET device in the process of curtailing and scaling [8].…”

Section: Introductionmentioning

confidence: 99%

“…In recent times, the tunnel field-effect transistor (TFET) has become a prominent substitute to the CFET by employing a distinct and unique carrier transport mechanism bandto-band tunneling form source to channel with a minimal gate voltage [8][9][10]. The TFET can exhibit a superior subthreshold swing (SS < 60 mv/dec), which is the key performance metric for designing highly efficient biosensors.…”

Section: Introductionmentioning

confidence: 99%

Nanowire gate all around-TFET-based biosensor by considering ambipolar transport

Reddy¹,

Panda²

2021

Appl. Phys. A

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A Comprehensive Review on Tunnel Field-Effect Transistor (TFET) Based Biosensors: Recent Advances and Future Prospects on Device Structure and Sensitivity

Cited by 61 publications

References 50 publications

Design and Simulation of InP and Silicon Nanowires With Different Channel Characteristic as Biosensors to Improve Output Sensitivity

Design and Simulation of InP and Silicon Nanowires With Different Channel Characteristic as Biosensors to Improve Output Sensitivity

Performance analysis of Z‐shaped gate dielectric modulated (DM) tunnel field‐effect transistor‐(TFET) based biosensor with extended horizontal N+ pocket

Nanowire gate all around-TFET-based biosensor by considering ambipolar transport

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