Monte Carlo Simulation of III–V Material-Based MOSFET for High Frequency and Ultra-Low Consumption Applications
High-mobility III–V heterostructures are emerging and very promising materials likely to fulfil high-speed and low-power specifications for ambient intelligent applications. The main objective of this work is to theoretically explore the potentialities of MOSFET based on III–V materials with low bandgap and high electron mobility. First, the charge control is studied in III–V MOS structures using a Schrödinger-Poisson solver. Electronic transport in III–V devices is then analyzed using a particle Monte Carlo device simulator. The external access resistances used in the calculations are carefully calibrated on experimental results. The performance of different structures of nanoscale MOS transistor based on III–V materials is evaluated and the quasi-ballistic character of electron transport is compared to that in Si transistors of same gate length.
Keywords: CHARGE CONTROL; III-V MATERIALS; INVERSION LAYER CAPACITANCE; MONTE CARLO SIMULATION; SEMICONDUCTOR DEVICE MODELLING
Document Type: Research Article
Publication date: 01 November 2010
- Journal for Nanoscience and Nanotechnology (JNN) is an international and multidisciplinary peer-reviewed journal with a wide-ranging coverage, consolidating research activities in all areas of nanoscience and nanotechnology into a single and unique reference source. JNN is the first cross-disciplinary journal to publish original full research articles, rapid communications of important new scientific and technological findings, timely state-of-the-art reviews with author's photo and short biography, and current research news encompassing the fundamental and applied research in all disciplines of science, engineering and medicine.
- Editorial Board
- Information for Authors
- Subscribe to this Title
- Terms & Conditions
- Ingenta Connect is not responsible for the content or availability of external websites
- Access Key
- Free content
- Partial Free content
- New content
- Open access content
- Partial Open access content
- Subscribed content
- Partial Subscribed content
- Free trial content