Title :
In-situ TEM tensile test of 90nm-thick 〈110〉 SCS beam using MEMS chip
Author :
Jin, Q.H. ; Li, T. ; Wang, Y.L. ; Li, X.X. ; Zhou, P. ; Xu, F.F.
Author_Institution :
SIMIT, Chinese Acad. of Sci., Shanghai
Abstract :
In-situ tensile testing in TEM (transmission electron microscopy) is a useful tool for studying mechanical properties of nano-structures because it can provide quantitative information on sample deformation at atomic scale. This paper reports an in-situ tensile testing on a 90 nm-thick <110> SCS nanobeam in TEM JOEL 2010 by using a self-made TEM holder and an MEMS tensile-testing chip. A suspended SCS nanobeam, a comb drive actuator, a force sensor beam, and an electron beam window were integrated into the chip, which is fabricated by means of Si bulk micromachining and wafer bonding techniques. The in-situ tensile tests on the 90 nm-thick SCS nanobeam demonstrated its strain-stress relationship, and indicated that the Youngpsilas modulus as 167 Gpa, which doesnpsilat present obvious size effect.
Keywords :
Young´s modulus; micromachining; micromechanical devices; nanotechnology; stress-strain relations; tensile testing; transmission electron microscopy; wafer bonding; MEMS tensile-testing chip; SCS nanobeam; Si bulk micromachining; Youngpsilas modulus; comb drive actuator; electron beam window; force sensor beam; in-situ TEM tensile test; mechanical properties; nanostructures; self-made TEM holder; single-crystal silicon nanobeam; strain-stress relationship; transmission electron microscopy; wafer bonding; Actuators; Electron beams; Force measurement; Force sensors; Laboratories; Mechanical factors; Micromechanical devices; Testing; Transmission electron microscopy; Wafer bonding;
Conference_Titel :
Sensors, 2008 IEEE
Conference_Location :
Lecce
Print_ISBN :
978-1-4244-2580-8
Electronic_ISBN :
1930-0395
DOI :
10.1109/ICSENS.2008.4716636
