Title :
Piezoresistivity Characterization of Synthetic Silicon Nanowires Using a MEMS Device
Author :
Zhang, Yong ; Liu, Xinyu ; Ru, Changhai ; Zhang, Yan Liang ; Dong, Lixin ; Sun, Yu
Author_Institution :
Adv. Micro & Nanosyst. Lab., Univ. of Toronto, Toronto, ON, Canada
Abstract :
This paper presents a microelectromechanical systems (MEMS) device for simultaneous electrical and mechanical characterization of individual nanowires. The device consists of an electrostatic actuator and two capacitive sensors, capable of acquiring all measurement data (force and displacement) electronically without relying on electron microscopy imaging. This capability avoids the effect of electron beam (e-beam) irradiation during nanomaterial testing. The bulk-microfabricated devices perform electrical characterization at different mechanical strain levels. To integrate individual nanowires to the MEMS device for testing, a nanomanipulation procedure is developed to transfer individual nanowires from their growth substrate to the device inside a scanning electron microscope. Silicon nanowires are characterized using the MEMS device for their piezoresistive as well as mechanical properties. It is also experimentally verified that e-beam irradiation can significantly alter the characterization results and must be avoided during testing.
Keywords :
actuators; electric sensing devices; electron beam effects; electron microscopy; elemental semiconductors; micromechanical devices; nanowires; piezoelectricity; scanning electron microscopy; silicon; MEMS device; Si; bulk-microfabricated devices; electrical characterization; electron beam irradiation; electron microscopy imaging; electrostatic actuator; microelectromechanical system device; nanomanipulation procedure; nanomaterial testing; piezoresistivity characterization; scanning electron microscope; synthetic silicon nanowires; two capacitive sensors; Actuators; Force sensors; Micromechanical devices; Nanoscale devices; Nanowires; Silicon; Testing; Electrical characterization; mechanical characterization; microelectromechanical systems (MEMS) tensile testing; nanomanipulation; piezoresistivity characterization; scanning electron microscope (SEM); silicon nanowires;
Journal_Title :
Microelectromechanical Systems, Journal of
DOI :
10.1109/JMEMS.2011.2153825
