Resistivity of a 2d quantum critical metal
Copyright policy )Resistivity of a 2d quantum critical metal
We calculate resistivity in the paramagnetic phase just above the curie temperature in a $2d$ ferromagnetic metal. The required dynamical susceptibility in the formalism of resistivity is calculated within the Random Phase Approximation(RPA). The mechanism of resistivity is magnetic scattering in which $s$-band electrons are scattered off the magnetic spin fluctuations of d-band electrons. We use the $s$-$d$ Hamiltonian formalism. We find that near the quantum critical point the resistivity in $2d$ scales as $T^{\frac{4}{3}}$, whereas in $3d$ it scales as $T^{\frac{5}{3}}$. In contrast to it, resistivity due to phonon scattering is given by $T^5$ in low temperature limit as is well known. Our RPA result agrees with the Self-Consistence Renormalisation(SCR) theory result.
11 pages
Statistical mechanics of semiconductors, Condensed Matter - Strongly Correlated Electrons, resistivity near a magnetic instability, Strongly Correlated Electrons (cond-mat.str-el), Statistical mechanics of magnetic materials, metal near quantum critical point, random phase approximation, Statistical mechanics of metals, \(s\)-\(d\) Hamiltonian formalism, FOS: Physical sciences, Renormalization group methods in equilibrium statistical mechanics
Statistical mechanics of semiconductors, Condensed Matter - Strongly Correlated Electrons, resistivity near a magnetic instability, Strongly Correlated Electrons (cond-mat.str-el), Statistical mechanics of magnetic materials, metal near quantum critical point, random phase approximation, Statistical mechanics of metals, \(s\)-\(d\) Hamiltonian formalism, FOS: Physical sciences, Renormalization group methods in equilibrium statistical mechanics
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