Optical Effects in an Electric Dipole Spin Polarised Relativistic Quantum Plasma
Abstract
The covariant, spin-dependent response tensor for an electric dipole moment polarized electron gas (statistical distribution of electrons and positrons) is calculated using the formalism of quantum plasmadynamics. A simultaneous eigenfunction of both the Dirac Hamiltonian and the electric moment spin operator is constructed. Expressions for the electric moment states and the corresponding vertex functions are derived. It is shown that when the distribution of momenta is isotropic, the spin dependent response of an electric moment dependent quantum plasma is identically zero. The response is non-zero in the presence of a streaming motion perpendicular to the axis if the electron and positron distributions are different. The response has the same form as for a plasma with a nonzero, cross field current when pi ≠ 0. This quantum relativistic correction is used to identify the dispersion equation for an electric moment spin polarised plasma with a streaming cold plasma background. In particular, the natural modes of an electric moment dependent quantum plasma exhibit elliptical polarisation. This is in contrast to a magnetic moment dependent electron gas, which is gyrotropic, or a helicity dependent electron gas which is optically active. The different responses, due to quantum plasmas being spin polarised by different relativistically acceptable spin operators, does not appear in other approaches to quantum plasma theory.
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