DocumentCode :
1424016
Title :
Giant Piezoresistance Measured in n-Type Nanothick Si Layer That Has Interface With 
Author :
Yang, Yongliang ; Li, Xinxin
Author_Institution :
State Key Lab. of Transducer Technol. & the Sci. & Technol., Chinese Acad. of Sci., Shanghai, China
Volume :
32
Issue :
3
fYear :
2011
fDate :
3/1/2011 12:00:00 AM
Firstpage :
411
Lastpage :
413
Abstract :
A giant piezoresistive coefficient is, for the first time, experimentally measured for n-type nanothick silicon. Compared to n-type bulk silicon, the nanothick silicon resistors exhibit at least one order of magnitude higher piezoresistive coefficient. Based on 2-D quantum confinement effect, our theoretic calculation indicates that the piezoresistive sensitivity will decrease and approach to zero, along with continually thinning the n-type silicon resistor. Thus, quantum effect is not responsible for the giant piezoresistance of the n-type nanothick silicon. By phenomenon analysis and qualitative modeling, we attribute the obtained giant piezoresistance to stress-enhanced Si/SiO2 interfacial electron trapping effect. Hence, the giant piezoresistance in n-type nano thick silicon is dominantly originated from electron concentration change, instead of equivalent mobility change in conventional piezoresistance of bulk silicon.
Keywords :
electron density; electron mobility; elemental semiconductors; interface states; piezoresistance; piezoresistive devices; semiconductor thin films; semiconductor-insulator boundaries; silicon; silicon compounds; thin film resistors; 2-D quantum confinement effect; Si-SiO2; electron concentration; equivalent mobility; giant piezoresistive coefficient; interfacial electron trapping; n-type nanothick silicon; nanothick silicon resistors; quantum effect; Interface effect; piezoresistance; quantum effect; silicon;
fLanguage :
English
Journal_Title :
Electron Device Letters, IEEE
Publisher :
ieee
ISSN :
0741-3106
Type :
jour
DOI :
10.1109/LED.2010.2098388
Filename :
5685796
Link To Document :
