A Flow Equation Approach Striving Towards an Energy-Separating Hamiltonian Unitary Equivalent to the Dirac Hamiltonian with Coupling to Electromagnetic Fields

Abstract

The Dirac Hamiltonian H(D) for relativistic charged fermions minimally coupled to (possibly time-dependent) electromagnetic fields is transformed with a purpose-built flow equation method, so that the result of that transformation is unitary equivalent to H(D) and granted to strive towards a limiting value H(NW) commuting with the Dirac β-matrix. Upon expansion of H(NW) to order v2c2 the nonrelativistic Hamiltonian H(SP) of Schr\"odinger-Pauli quantum mechanics emerges as the leading order term adding to the rest energy mc2. All the relativistic corrections to H(SP) are explicitly taken into account in the guise of a Magnus type series expansion, the series coefficients generated to order (v2c2)n for n≥2 comprising partial sums of iterated commutators only. In the special case of static fields the equivalence of the flow equation method with the well known energy-separating unitary transformation of Eriksen is established on the basis of an exact solution of a reverse flow equation transforming the β-matrix into the energy-sign operator associated with H(D). That way the identity H(NW)=βH(NW)H(NW) is established implying H(NW) being determined unambiguously.

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