Title :
Giant Piezoresistance of Nano-Thick Silicon Induced by Interface Electron Traping Effect
Author :
Yang, Yongliang ; Li, Xinxin
Author_Institution :
Shanghai Inst. of Microsyst. & Inf. Technol., Chinese Acad. of Sci., Shanghai, China
Abstract :
Both n- and p-type nano-thick piezoresistors are fabricated on SOI (silicon on insulator) wafers using micro-fabrication processes. Giant piezoresistance is measured and theoretically explained for nano-thick silicon resistors. Compared to bulk silicon, one order of magnitude higher piezoresistive coefficients are, for the first time, tested with 13 nm-thick n-type and 9 nm p-type samples. Surpassing 2-D quantum effect, Si-SiO2 interface electron trapping effect dominates the giant piezoresistance. Different from equivalent mobility change in conventional piezoresistance of bulk silicon, the giant piezoresistance come from carrier concentration change and have the same effect on the longitudinal and transverse piezoresistors.
Keywords :
microfabrication; nanotechnology; piezoresistive devices; resistors; silicon compounds; silicon-on-insulator; SOI wafers; Si-SiO2; giant piezoresistance; interface electron traping effect; micro-fabrication processes; n-type nano-thick piezoresistors; nano-thick silicon resistors; p-type nano-thick piezoresistors; silicon on insulator wafers; size 13 nm; size 9 nm; Electron traps; Fabrication; Mechanical sensors; Piezoresistance; Piezoresistive devices; Potential well; Resistors; Silicon on insulator technology; Stress; Testing;
Conference_Titel :
Micro Electro Mechanical Systems, 2009. MEMS 2009. IEEE 22nd International Conference on
Conference_Location :
Sorrento
Print_ISBN :
978-1-4244-2977-6
Electronic_ISBN :
1084-6999
DOI :
10.1109/MEMSYS.2009.4805442
