Add to ORKGWe investigate the metal–insulator transition in 2D electron systems assuming a percolation mechanism connecting through a network of metallic domains. The size of the domains is determined by the level of disorder and the strength of the electron correlations. The domains are linked through quantum tunneling. We determine the dependence of the resistivity on electron density and temperature by calculating the tunnelling transmission through the potential barriers between the domains. The results are in good agreement with recent experimental measurements
We investigate transport in 2D mesoscopic electron systems with disorder assuming a percolation mech...
We have studied the quantum corrections to the resistance of two-dimensional (2D) percolation networ...
We discuss the metal–insulator transition phenomenon in two dimensions in terms of a quantum critica...
We investigate the metal–insulator transition in 2D electron systems assuming a percolation mechanis...
We investigate the metal–insulator transition in 2D electron systems assuming a percolation mechanis...
We investigate the metal–insulator transition in 2D electron systems assuming a percolation mechanis...
We investigate the metal-insulator transition in 2D electron systems assuming a percolation mechanis...
We investigate the metal-insulator transition in 2D electron systems assuming a percolation mechanis...
Motivated by recent surprising experimental results for temperature dependent resistivities in 2D m...
Motivated by recent surprising experimental results for temperature dependent resistivities in 2D m...
Motivated by recent surprising experimental results for temperature dependent resistivities in 2D m...
Motivated by recent surprising experimental results for temperature dependent resistivities in 2D m...
Motivated by recent surprising experimental results for temperature dependent resistivities in 2D m...
Motivated by recent surprising experimental results for temperature dependent resistivities in 2D m...
We investigate transport in 2D mesoscopic electron systems with disorder assuming a percolation mech...
We investigate transport in 2D mesoscopic electron systems with disorder assuming a percolation mech...
We have studied the quantum corrections to the resistance of two-dimensional (2D) percolation networ...
We discuss the metal–insulator transition phenomenon in two dimensions in terms of a quantum critica...
We investigate the metal–insulator transition in 2D electron systems assuming a percolation mechanis...
We investigate the metal–insulator transition in 2D electron systems assuming a percolation mechanis...
We investigate the metal–insulator transition in 2D electron systems assuming a percolation mechanis...
We investigate the metal-insulator transition in 2D electron systems assuming a percolation mechanis...
We investigate the metal-insulator transition in 2D electron systems assuming a percolation mechanis...
Motivated by recent surprising experimental results for temperature dependent resistivities in 2D m...
Motivated by recent surprising experimental results for temperature dependent resistivities in 2D m...
Motivated by recent surprising experimental results for temperature dependent resistivities in 2D m...
Motivated by recent surprising experimental results for temperature dependent resistivities in 2D m...
Motivated by recent surprising experimental results for temperature dependent resistivities in 2D m...
Motivated by recent surprising experimental results for temperature dependent resistivities in 2D m...
We investigate transport in 2D mesoscopic electron systems with disorder assuming a percolation mech...
We investigate transport in 2D mesoscopic electron systems with disorder assuming a percolation mech...
We have studied the quantum corrections to the resistance of two-dimensional (2D) percolation networ...
We discuss the metal–insulator transition phenomenon in two dimensions in terms of a quantum critica...