Performance investigation of a semi‐junctionless type II heterojunction tunnel field effect transistor in nanoscale regime

Abstract: In this work, the electrical characteristics and impact of physical and structural parameters on the performance of a novel heterojunction GaAs 0.1 Sb 0.9-InAs semi-junctionless tunnel field effect transistor (SJTFET) is demonstrated. Unlike the conventional p-in tunnel field effect transistor, the n-channel SJTFET is a p +-p +-n structure having similar doping profile for the source and channel regions. First, all the structural and physical parameters are set to their initial values, and then, one parameter … Show more

“…Equation 1 shows the probability of tunneling in a TFET device, in which Wentzel-Kramers-Brillouin approximation is used [12,16].…”

“…Nonlocal BTBT model considers spatial variations of energy bands and quasi-fermi levels in tunneling path [22,29]. The Hansch model is used to consider the quantum confinement effect as well as interface defects of oxide/semiconductor [12,29]. The dependence of the mobility on the vertical electric field, doping concentration, and temperature is considered using Lombardi model [22,29].…”

“…However, the ultra-sharp doping concentration gradient in the source/channel and the drain/channel junctions complicates the fabrication process of TFET device in nanometer regime [6,7]. Recently, a junctionless TFET (JLTFET) has been proposed, in which issues caused by ultra-sharp doping concentration gradient in the source/channel and the drain/channel junctions are eliminated [6][7][8][9][10][11][12]. JLTFET is a heavy doped thin film semiconductor, in which the type and level of doping are unchanged throughout the device.…”

“…Our simulation results show that selecting a material with larger band gap in the drain-channel region as well as a material with smaller band gap in the source region in VHJL-TFET device drastically reduce the ambipolarity behavior. Based on the simulation results, the improvement of the SS and ON-state current to OFFstate current (ION/IOFF) ratio of VHJL-TFET structure with Y=0.85 and X=0.8 is noticeable compared to the recently proposed structures [11,12,18,21,22,26]. With changes in X and Y, in addition to energy band gap and electron affinity, the electron tunneling effective mass and hole tunneling effective mass are also changed [27].…”

Investigation of the impact of mole-fraction on the digital benchmarking parameters as well as sensitivity in GaXIn1−XAs/GaYIn1−YSb vertical heterojunctionless tunneling field effect transistor

“…Equation 1 shows the probability of tunneling in a TFET device, in which Wentzel-Kramers-Brillouin approximation is used [12,16].…”

“…Nonlocal BTBT model considers spatial variations of energy bands and quasi-fermi levels in tunneling path [22,29]. The Hansch model is used to consider the quantum confinement effect as well as interface defects of oxide/semiconductor [12,29]. The dependence of the mobility on the vertical electric field, doping concentration, and temperature is considered using Lombardi model [22,29].…”

“…However, the ultra-sharp doping concentration gradient in the source/channel and the drain/channel junctions complicates the fabrication process of TFET device in nanometer regime [6,7]. Recently, a junctionless TFET (JLTFET) has been proposed, in which issues caused by ultra-sharp doping concentration gradient in the source/channel and the drain/channel junctions are eliminated [6][7][8][9][10][11][12]. JLTFET is a heavy doped thin film semiconductor, in which the type and level of doping are unchanged throughout the device.…”

“…Our simulation results show that selecting a material with larger band gap in the drain-channel region as well as a material with smaller band gap in the source region in VHJL-TFET device drastically reduce the ambipolarity behavior. Based on the simulation results, the improvement of the SS and ON-state current to OFFstate current (ION/IOFF) ratio of VHJL-TFET structure with Y=0.85 and X=0.8 is noticeable compared to the recently proposed structures [11,12,18,21,22,26]. With changes in X and Y, in addition to energy band gap and electron affinity, the electron tunneling effective mass and hole tunneling effective mass are also changed [27].…”

Investigation of the impact of mole-fraction on the digital benchmarking parameters as well as sensitivity in GaXIn1−XAs/GaYIn1−YSb vertical heterojunctionless tunneling field effect transistor

Performance investigation of steep-slope core–shell nanotube indium nitride electron–hole bilayer tunnel field effect transistor

Design and Analysis of a Heterojunction Vertical t-Shaped Tunnel Field Effect Transistor