Charge density waves and superconductivity in the electron-positive fermion gas using a simple intuitive model. Part II: Collective modes, effective interactions, superconductivity, and transport
Abstract
Superconductivity and the normal state electrical resistivity which varies as T2 are strongly enhanced near the compressibility and charge density wave instabilities in the electron-positive fermion gas. The additional screening from the positive fermions introduces an attractive term in the effective electron-electron interaction that is the basis for superconductivity. Electron-positive fermion scattering is the source of the T2 term in the electrical resistivity. At an instability, both interactions are divergent. The superconducting transition temperature is estimated using the McMillan formula. The electron-positive fermion gas conducts electricity and heat. Because electron-electron and positive fermion-positive fermion scattering conserve momentum, they do not contribute to the electrical resistivity, but electron-positive fermion scattering does. All three scattering mechanisms contribute to the thermal resistivity. The simple model for the electron-positive fermion gas is physically intuitive and naturally introduces instabilities at q=0 when the bulk modulus becomes zero and charge density waves at finite q under some circumstances. For each mass ratio M/m, there is a unique density rs where the energy is a minimum. For different mass ratios, the interactions are investigated at several values of rs ranging from below the energy minimum to that of the instability.
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