Variation of source gate workfunction on the performance of dual material gate rectangular recessed channel SOI‐MOSFET

Abstract: This paper attempts to propose a new device as workfunction modulated dual metal rectangular recessed channel silicon on insulator (WMDMRRC-SOI) MOSFET. This model takes the advantage of recessed channel to reduce the hot-carrier effect and a linear variation of workfunction at source side metal gate to achieve improved threshold voltage and electron transportation efficiency. The characteristics of WMDMRRC-SOI MOSFET are analyzed in terms of electron behaviour like mobility, temperature, and velocity in th… Show more

“…Again the threshold voltage is termed as the minimum voltage required to make device turn on. This is calculated by the value of gate voltage V gs for which minimum surface potential equals to the twice of Fermi potential [35,57]. Drain current varies with applied gate voltage at constant drain to source voltage V .…”

“…A dual metal (DM) gate with a nano-cavity length (l nc ) of 8 nm, oxide-thickness (t ox ) of 2 nm, and gate length (L G ) of 20 nm is implemented in the proposed biosensor [23]. As the implementaion of higher gate workfunction near to the source end offers an improve sensitivity for which the metal workfunction of M1 = 4.7 eV, and M2 = 4.1 eV are being considered in the gate region [35,37]. Again the specification of the stack source/drain formed by silicon and germanium material is taken as reported in [40].…”

“…However, the transport efficiency of the recessed channel (RC) MOS deteriorates due to the presence of the groove corner which affects the device threshold voltage. Therefore with the help of workfunction engineering and stack source/drain, the channel field can be improved to boost the carrier transport efficiency that may give better sensitivity for biosensors [34][35][36][37]. Now a days, the silicon-on-insulator (SOI) technique provides a better isolation between channel and body to enhance the device SCEs.…”

Gate electrode stacked source/drain SON trench MOSFET for biosensing application

“…Again the threshold voltage is termed as the minimum voltage required to make device turn on. This is calculated by the value of gate voltage V gs for which minimum surface potential equals to the twice of Fermi potential [35,57]. Drain current varies with applied gate voltage at constant drain to source voltage V .…”

“…A dual metal (DM) gate with a nano-cavity length (l nc ) of 8 nm, oxide-thickness (t ox ) of 2 nm, and gate length (L G ) of 20 nm is implemented in the proposed biosensor [23]. As the implementaion of higher gate workfunction near to the source end offers an improve sensitivity for which the metal workfunction of M1 = 4.7 eV, and M2 = 4.1 eV are being considered in the gate region [35,37]. Again the specification of the stack source/drain formed by silicon and germanium material is taken as reported in [40].…”

“…However, the transport efficiency of the recessed channel (RC) MOS deteriorates due to the presence of the groove corner which affects the device threshold voltage. Therefore with the help of workfunction engineering and stack source/drain, the channel field can be improved to boost the carrier transport efficiency that may give better sensitivity for biosensors [34][35][36][37]. Now a days, the silicon-on-insulator (SOI) technique provides a better isolation between channel and body to enhance the device SCEs.…”

Gate electrode stacked source/drain SON trench MOSFET for biosensing application

“…Moreover, gate workfuction of the device is directly proportional to threshold voltage. The threshold voltage of MGW device is more as compared to the SGW device and high V th devices are mostly preferable for space applications [15,21,[30][31][32][42][43][44][45][46][47].…”

Improved post-radiation behavior of FinFET based CMOS with workfunction modulated gate

A Compact Analytical Model and Electrostatic Performance Investigation of Multilayer Groove Gate SOI-MOSFET