Melting of a 2D Quantum Electron Solid in High Magnetic Field
Abstract
The melting temperature (Tm) of a solid is generally determined by the pressure applied to it, or indirectly by its density (n) through the equation of state. This remains true even for helium solidswilk:67, where quantum effects often lead to unusual propertiesekim:04. In this letter we present experimental evidence to show that for a two dimensional (2D) solid formed by electrons in a semiconductor sample under a strong perpendicular magnetic fieldshay:97 (B), the Tm is not controlled by n, but effectively by the quantum correlation between the electrons through the Landau level filling factor =nh/eB. Such melting behavior, different from that of all other known solids (including a classical 2D electron solid at zero magnetic fieldgrim:79), attests to the quantum nature of the magnetic field induced electron solid. Moreover, we found the Tm to increase with the strength of the sample-dependent disorder that pins the electron solid.
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