Title :
Simulation of charge transfer in GaAs cermet-gate CCDs
Author :
Pennathur, S. ; Kwok, H.H.L.
Author_Institution :
Dept. of Electr. & Comput. Eng., Victoria Univ., BC, Canada
Abstract :
Computer simulations of charge transport in GaAs cermet-gate charge-coupled devices (CCDs) are reported. A finite difference scheme was used to simulate charge evolution between successive clock phases. Epi-grown and ion-implanted channels were considered. As observed, the charge transport, and hence the transfer inefficiencies of these devices, depended on the relative importance of the drift field and the self-induced field more than the diffusion contribution. While the self-induced drift effect aided the charge transport at the initial phase, its effect at the final stage of charge transfer would be to reverse the charge transport. Velocity saturation effect is another limiting factor affecting charge transfer. Both the velocity saturation effect and the reverse self-induced drift effect were responsible for the retardation of the charge transfer
Keywords :
III-V semiconductors; cermets; charge-coupled devices; digital simulation; electronic engineering computing; gallium arsenide; semiconductor device models; GaAs; III-V semiconductors; cermet-gate charge-coupled devices; charge evolution; charge transfer; charge transport; computer simulations; drift field; finite difference method; ion-implanted channels; self-induced field; successive clock phases; transfer inefficiencies; velocity saturation effect; Ceramics; Charge coupled devices; Charge transfer; Computational modeling; Doping; Electrodes; Electron mobility; Equations; Finite difference methods; Gallium arsenide;
Conference_Titel :
Communications, Computers and Signal Processing, 1991., IEEE Pacific Rim Conference on
Conference_Location :
Victoria, BC
Print_ISBN :
0-87942-638-1
DOI :
10.1109/PACRIM.1991.160791
