论文信息 - Conductance distribution in granular metal films: a combined study by conducting atomic force microscopy and computer simulation

Conductance distribution in granular metal films: a combined study by conducting atomic force microscopy and computer simulation

Abstract We have studied the shape of the distribution F(G) for the conductance G between points on the surface of a metal–insulator nanocomposite film and the conducting substrate by Conducting Atomic Force Microscopy and computer simulation. Random resistor networks with both metallic and tunneling bonds included are used to model the nanocomposite films. The shape of F(G) is determined mainly by the connectivity of metal particles and the maximum tunneling distance in the composite. By qualitatively comparing the simulation results with the experimental data on granular NiFe-SiO2 films near the metal–insulator transition, we find important implications for the understanding of microscopic conduction mechanisms near the metal–insulator transition.

[1] Localization in the metallic regime of granular Cu—SiO2 films , 1982 .

[2] A. Sarychev,et al. New scaling for ac properties of percolating composite materials. , 1994, Physical review letters.

[3] A. B. Pakhomov,et al. Giant Hall effect in percolating ferromagnetic granular metal‐insulator films , 1995 .

[4] A. B. Pakhomov,et al. Probing the conducting paths in a metal - insulator composite by conducting atomic force microscopy , 1996 .

[5] G. Cody,et al. Physical Phenomena in Granular Materials , 1990 .

[6] Alexander L. Efros,et al. Electronic Properties of Doped Semi-conductors , 1984 .

[7] Yan,et al. Effect of annealing on the giant Hall effect. , 1996, Physical review. B, Condensed matter.