Title :
FEM modeling of vertically integrated nanogenerators in compression and flexion modes
Author :
Tao, R. ; Hinchet, R. ; Ardila, G. ; Montes, L. ; Mouis, M.
Author_Institution :
Univ. Joseph Fourier, Louis Nèel, France
fDate :
June 30 2014-July 3 2014
Abstract :
This paper analyzes the working principle and structure strength of vertically integrated piezoelectric nanowires into active devices for sensing or energy harvesting applications. Finite element method simulations have been used to evaluate the performances of the devices working in flexion and compression modes under varying input pressure. The geometric influence on the energy generation is also analyzed.
Keywords :
electric generators; energy harvesting; finite element analysis; nanowires; piezoelectric transducers; FEM modeling; compression modes; energy generation; energy harvesting applications; finite element method; flexion modes; sensing applications; vertically integrated nanogenerators; vertically integrated piezoelectric nanowires; Electric potential; Electrodes; Energy conversion; Finite element analysis; Geometry; Strain; Zinc oxide; energy harvesting; flexible device; nanogenerators; piezoelectric nanowires; sensing;
Conference_Titel :
Ph.D. Research in Microelectronics and Electronics (PRIME), 2014 10th Conference on
Conference_Location :
Grenoble
DOI :
10.1109/PRIME.2014.6872742
