Electric field scaling at a B=0 metal-insulator transition in two dimensions
Kravchenko, S. V.; Simonian, D.; Sarachik, M. P.; Mason, Whitney; Furneaux, J. E.;
Electric field scaling at a B=0 metal-insulator transition in two dimensions
The non-linear (electric field-dependent) resistivity of the 2D electron system in silicon exhibits scaling as a function of electric field and electron density in both the metallic and insulating phases, providing further evidence for a true metal-insulator transition in this 2D system at B=0. Comparison with the temperature scaling yields separate determinations of the correlation length exponent, ��=1.5, and the dynamical exponent, z=0.8, close to the theoretical value z=1.
We have slightly changed discussion after a conversation with B. I. Shklovskii whom we thank very much
- University of Oklahoma United States
Condensed Matter (cond-mat), FOS: Physical sciences, Condensed Matter
Condensed Matter (cond-mat), FOS: Physical sciences, Condensed Matter
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