A multiscale approach is pursued to develop a modified shear-lag model for capturing size-scale effects on electrostatic potential generated by a zinc oxide (ZnO) nanowire (NW) in a nanocomposite electrical generator (NCEG). The size-scale effect on elastic modulus of ZnO NWs is captured using a core-surface model. Closed form of governing equations is derived considering linear elasticity for axisymmetric problem and cylindrical coordinate system. Two different configurations based on parallel and series connecting of NCEGs for application in NEMS/MEMS devices are also studied. Parametric studies are performed for sample cases to demonstrate application of the developed model. It is shown that aspect ratio and diameter of NWs are crucial controlling parameters for determining the performance of nanocomposite electrical generators. Numerical results disclose that there is an optimum aspect ratio for each NW of specific diameter. It was also shown that despite the symmetry of loading with respect to mid-plane normal to the NW's axis, the electric potential is not symmetric.

• 出版日期2014-3