Title :
Positive Bias Instability and Recovery in InGaAs Channel nMOSFETs
Author :
Deora, S. ; Bersuker, Gennadi ; Loh, W.-Y. ; Veksler, Dekel ; Matthews, K. ; Kim, Tae Wook ; Lee, Rinus T. P. ; Hill, R.J.W. ; Kim, Do-Hyeon ; Wang, W.-E. ; Hobbs, Chris ; Kirsch, P.D.
Author_Institution :
SEMATECH, Albany, NY, USA
Abstract :
Instability of InGaAs channel nMOSFETs with the Al2O3/ ZrO2 gate stack under positive bias stress demonstrates recoverable and unrecoverable components, which can be tentatively assigned to the pre-existing and generated defects, respectively. The recoverable component is determined to be primarily associated with the defects in the Al2O3 interfacial layer (IL), the slow trapping at which is responsible for the power law time dependency of the threshold voltage shift and transconductance change. The fast electron trapping in the ZrO2 film exhibits negligible recovery, in contrast to the Si-based devices with a similar high-k dielectric film. Generation of new electron trapping defects is found to occur in the IL, preferentially in the region close to the substrate, while trap generation in the high-k dielectric is negligible.
Keywords :
III-V semiconductors; MOSFET; aluminium compounds; electron traps; gallium arsenide; high-k dielectric thin films; indium compounds; semiconductor device reliability; semiconductor-insulator boundaries; zirconium compounds; Al2O3-ZrO2; InGaAs; electron trapping defect; fast electron trapping; generated defect; high-K dielectric film; interfacial layer; nMOSFET; positive bias instability; positive bias recovery; positive bias stress; power law time dependency; preexisting defect; slow trapping; threshold voltage shift; transconductance change; trap generation; Charge carrier processes; High K dielectric materials; Indium gallium arsenide; Logic gates; Stress; Stress measurement; Substrates; $Delta V_{T}$; III-V; InGaAs; PBTI; reliability; trapping;
Journal_Title :
Device and Materials Reliability, IEEE Transactions on
DOI :
10.1109/TDMR.2013.2284376
