Quantifying Self-Heating Effects in Strained Si MOSFETs with Scaling

Author

Agaiby, Rimoon ; Neill, Anthony O. ; Olsen, Sarah ; Eneman, Geert ; Verheyen, Peter ; Loo, Roger ; Claeys, Cor

Author_Institution

Sch. of Electr., Electron. & Comput. Eng., Newcastle upon Tyne Univ.

fYear

2006

fDate

Sept. 2006

Firstpage

97

Lastpage

100

Abstract

This paper presents the first demonstration and quantification of the reduced self-heating effects in deep submicron n-MOSFETs on thin strain relaxed buffers (SRB), through the application of the ac conductance technique. Strained Si devices demonstrate a peak enhancement in on-state drain current, I_on ~ 30 %, with this figure falling to 6 % at smaller gate lengths. After applying the ac conductance technique the 30 % enhancement remains almost constant across the range of gate lengths. These results prove that the previously known trend of reduced enhancement with device scaling in strained Si devices on SRBs was largely due to self-heating effects. Comparison of the self-heating effects in SOI and Si_0.8 Ge _0.2 SRBs reveal the potential for thin SRBs as a viable performance booster into the deep sub-micron regime

Keywords

Ge-Si alloys; MOSFET; buffer layers; silicon; silicon-on-insulator; MOSFET; SOI; Si; Si_0.8 Ge_0.2; ac conductance technique; self-heating effects; strained devices; thin strain relaxed buffers; Capacitive sensors; Costs; Fabrication; Germanium silicon alloys; Helium; MOSFET circuits; Maintenance engineering; Silicon germanium; Temperature; Thermal conductivity;

fLanguage

English

Publisher

ieee

Conference_Titel

Solid-State Device Research Conference, 2006. ESSDERC 2006. Proceeding of the 36th European

Conference_Location

Montreux

ISSN

1930-8876

Print_ISBN

1-4244-0301-4

Type

conf

DOI

10.1109/ESSDER.2006.307647

Filename

4099865