Drain-induced barrier lowering

About: Drain-induced barrier lowering is a research topic. Over the lifetime, 6163 publications have been published within this topic receiving 101547 citations.

Method of making asymmetric low power MOS devices

Abstract: Low threshold voltage MOS devices having asymmetric halo implants are disclosed herein. An asymmetric halo implant provides a pocket region located under a device's source or drain near where the source (or drain) edge abuts the device's channel region. The pocket region has the same conductivity type as the device's bulk (albeit at a higher dopant concentration) and, of course, the opposite conductivity type as the device's source and drain. Only the source or drain, not both, have the primary pocket region. An asymmetric halo device behaves like two pseudo-MOS devices in series: a "source FET" and a "drain FET." If the pocket implant is located under the source, the source FET will have a higher threshold voltage and a much shorter effective channel length than the drain FET.

Low voltage one transistor flash EEPROM cell using Fowler-Nordheim programming and erase

Abstract: A single transistor electrically erasable programmable memory device capable of being programmed and erased using Fowler-Nordheim tunneling and capable of being operated using low voltages. Portions of each of the source and drain regions overlap with the first gate dielectric layer, and the interpoly dielectric layer is chosen to have a high dielectric constant so as to maximize the capacitive coupling ratio between floating gate, control gate, source, and drain. The logical condition of cells in the array is set by first elevating a block of cells to a high voltage threshold and by individually lowering the voltage threshold of selected cells.

Vertical Silicon Nanowire Field Effect Transistors with Nanoscale Gate-All-Around

Abstract: Nanowires are considered building blocks for the ultimate scaling of MOS transistors, capable of pushing devices until the most extreme boundaries of miniaturization thanks to their physical and geometrical properties. In particular, nanowires’ suitability for forming a gate-all-around (GAA) configuration confers to the device an optimum electrostatic control of the gate over the conduction channel and then a better immunity against the short channel effects (SCE). In this letter, a large-scale process of GAA vertical silicon nanowire (VNW) MOSFETs is presented. A top-down approach is adopted for the realization of VNWs with an optimum reproducibility followed by thin layer engineering at nanoscale. Good overall electrical performances were obtained, with excellent electrostatic behavior (a subthreshold slope (SS) of 95 mV/dec and a drain induced barrier lowering (DIBL) of 25 mV/V) for a 15-nm gate length. Finally, a first demonstration of dual integration of n-type and p-type VNW transistors for the realization of CMOS inverter is proposed.

A Three-Dimensional Simulation Study of the Performance of Carbon Nanotube Field-Effect Transistors With Doped Reservoirs and Realistic Geometry

Abstract: This paper simulates the expected device performance and scaling perspectives of carbon nanotube (CNT) field-effect transistors with doped source and drain extensions. The simulations are based on the self-consistent solution of the three-dimensional Poisson-Schroumldinger equation with open boundary conditions, within the nonequilibrium Green's function formalism, where arbitrary gate geometry and device architecture can be considered. The investigation of short channel effects for different gate configurations and geometry parameters shows that double-gate devices offer quasi-ideal subthreshold slope and drain-induced barrier lowering without extremely thin gate dielectrics. Exploration of devices with parallel CNTs shows that on currents per unit width can be significantly larger than the silicon counterpart, while high-frequency performance is very promising

Fermi threshold field effect transistor

Abstract: A field effect transistor (FET) operates in the enhancement mode without requiring inversion by setting the device's threshold voltage to twice the Fermi potential of the semiconductor material. The FET, referred to as a Fermi Threshold FET or Fermi-FET, has a threshold voltage which is independent of oxide thickness, channel length, drain voltage and substrate doping, the vertical electric field in the channel becomes zero, thereby maximizing carrier mobility, and minimizing hot electron effects. A high speed device, substantially independent of device dimensions is thereby provided, which may be manufactured using relaxed groundrules, to provide low cost, high yield devices. Temperature dependence of threshold voltage may also be eliminated by providing a semiconductor gate contact which neutralizes the effect of substrate contact potential. Source and drain subdiffusion regions may be provided to simultaneously maximize the punch-through and impact ionization voltages of the devices, so that short channel devices do not require scaled-down power supply voltages. Multi gate devices may be provided. An accelerator gate, adjacent the drain, may further improve performance. The Fermi-FET criteria may be maintained, while allowing for a deep channel by providing a substrate contact for the Fermi-FET and applying a substrate bias to this contact. Substrate enhancement pocket regions adjacent the source and drain regions may be provided to produce a continuous depletion region under the source, drain and channel regions to thereby minimize punch-through effects.