Title :
Reliability scaling issues for nanoscale devices
Author :
McMahon, William ; Haggag, Amr ; Hess, Karl
Author_Institution :
Beckman Inst., Univ. of Illinois, Urbana, IL, USA
fDate :
3/1/2003 12:00:00 AM
Abstract :
We discuss two specific scaling issues that can result in qualitative changes in device reliability prediction for nanoscale devices. The first of these involves a rapid increase in early failures due to a distribution of activation energies of defect precursors. We show that the slopes of the failure functions for hot carrier interface state generation (HCI) and time-dependent dielectric breakdown (TDDB) have simple physical interpretations in terms of a geometrical factor and the activation energy distribution width. The second issue involves a transition from single to multiple electrons causing individual defects. This picture allows simple physical explanations for the larger HCI damage in NMOS versus PMOS, the anomalous isotope effect of activation energies for HCI in the lucky electron model, and the observed power law dependence of the time to breakdown versus voltage for TDDB for ultrathin oxides.
Keywords :
MOSFET; dielectric thin films; hot carriers; interface states; nanoelectronics; semiconductor device breakdown; semiconductor device models; semiconductor device reliability; MOSFET; NMOS; PMOS; TDDB; Weibull slopes; activation energy distribution width; anomalous isotope effect; failure functions; geometrical factor; hot carrier interface state generation; hot carriers; lucky electron model; nanoscale devices; power law dependence; reliability scaling issues; time to breakdown; time-dependent dielectric breakdown; ultrathin oxides; Breakdown voltage; Electric breakdown; Electrons; Energy barrier; Hot carriers; Human computer interaction; Interface states; Nanoscale devices; Scattering; Silicon;
Journal_Title :
Nanotechnology, IEEE Transactions on
DOI :
10.1109/TNANO.2003.808515
