Title :
Numerical simulation of electron transport through constriction in a metallic thin film
Author :
Gurrum, Siva P. ; Joshi, Yogendra K. ; King, William P. ; Ramakrishna, Koneru
Author_Institution :
George W. Woodruff Sch. of Mech. Eng., Georgia Inst. of Technol., Atlanta, GA, USA
Abstract :
Electron transport through a constriction in a thin metallic film of finite thickness is simulated by numerically solving the Boltzmann transport equation (BTE) within the relaxation time approximation under linear response conditions. Such a structure closely represents vias connecting metal levels of different widths. Predicted reduction in effective electrical conductance due to electron surface scattering, which is significant when the dimensions are of the order of carrier mean free path, is compared with that for a constriction between semi-infinite spaces available in the literature. A simple expression for the size effect on conductance is fit to the simulated results applicable for constriction in a finite size thin film. The results could enable better estimate of effective resistance of next generation on-chip interconnections.
Keywords :
Boltzmann equation; electrical conductivity; electron mean free path; electron mobility; integrated circuit interconnections; metallic thin films; numerical analysis; surface scattering; Boltzmann transport equation; constriction size effect; electrical conductivity; electron surface scattering; electron transport; metallic thin film; numerical simulation; on-chip interconnections; relaxation time approximation; thin-film circuit interconnections; Apertures; CMOS technology; Electrons; Integrated circuit interconnections; Joining processes; Numerical simulation; Particle scattering; Space technology; Thin film circuits; Transistors; Constriction size effect; electrical conductivity; electron transport; thin-film circuit interconnections;
Journal_Title :
Electron Device Letters, IEEE
DOI :
10.1109/LED.2004.835538
