Conference Publication Details
Mandatory Fields
Shayesteh, M,Duffy, R,McCarthy, B,Blake, A,White, M,Scully, J,Yu, R,Djara, V,Schmidt, M,Petkov, N,Kelleher, AM,Roozeboom, F,Kwong, DL,Timans, PJ,Gusev, EP,Iwai, H,Ozturk, MC,Narayanan V
Germanium Fin Structure Optimization for Future MugFET and FinFET Applications
SILICON COMPATIBLE MATERIALS, PROCESSES, AND TECHNOLOGIES FOR ADVANCED INTEGRATED CIRCUITS AND EMERGING APPLICATIONS
2011
November
Validated
1
WOS: 2 ()
Optional Fields
PERFORMANCE
27
34
(100) germanium wafers were patterned by e-beam lithography with various exposure doses, in combination with dry etch, resulting in fin structures with widths in the range of 20-150 nm with a high aspect ratio, running in either the [100] or [110] direction. Fins were also subjected to various anneals in N-2 to examine germanium desorption but little or no size reduction was observed for typical dopant activation thermal budgets. Other samples received a phosphorus implant (at 7 degrees) that partially amorphized the structures. The amorphous depth was 120 nm. Subsequently a 400 degrees C 3 min furnace anneal in N-2 recrystallized the wide fins completely, leading to the formation of various defects, including twin boundaries, small localized defects, and stacking faults. Recrystallization was retarded in narrow fins as was reported in silicon fins.
10.1149/1.3568845
Grant Details