Title :
Thermal simulation techniques for nanoscale transistors
Author :
Rowlette, Jeremy ; Pop, Eric ; Sinha, Sanjiv ; Panzer, Mathew ; Goodson, Kenneth
Author_Institution :
Dept. of Electr. & Mech. Eng., Stanford Univ., CA, USA
Abstract :
Thermal simulations are important for advanced electronic systems at multiple length scales. A major challenge involves electrothermal phenomena within nanoscale transistors, which exhibit nearly ballistic transport both for electrons and phonons. The thermal device behavior can influence both the mobility and the leakage currents. We discuss recent advances in modeling coupled electron-phonon transport in future nanoscale transistors. The solution techniques involve solving the Boltzmann transport equation (BTE) for both electrons and phonons. We present a practical method for coupling an electron Monte Carlo simulation with an analytic "split-flux" form of the phonon BTE. We use this approach to model self-heating in a 20 nm quasi-ballistic n+/n/n+ silicon diode, and to investigate the role of hot electron and hot phonon transport.
Keywords :
Boltzmann equation; Monte Carlo methods; ballistic transport; electron transport theory; high electron mobility transistors; hot electron transistors; leakage currents; nanoelectronics; semiconductor device models; semiconductor diodes; silicon; thermal analysis; 20 nm; Boltzmann transport equation; Monte Carlo simulation; Si; ballistic transport; electron-phonon transport; electrothermal phenomena; hot electrons; hot phonon transport; leakage currents; nanoscale transistors; quasi-ballistic silicon diode; self-heating model; split-flux form; thermal device behavior; thermal simulation techniques; Computational modeling; Distribution functions; Electrons; Equations; Heating; Mechanical engineering; Particle scattering; Phonons; Silicon; Transistors;
Conference_Titel :
Computer-Aided Design, 2005. ICCAD-2005. IEEE/ACM International Conference on
Print_ISBN :
0-7803-9254-X
DOI :
10.1109/ICCAD.2005.1560068
