Modified similarity renormalization of Hamiltonians. Positronium on the light front
Abstract
Modified similarity renormalization (MSR) of Hamiltonians is proposed, that performes by means of flow equations the similarity transformation of Hamiltonian in the particle number space. This enables to renormalize in the energy space the field theoretical Hamiltonian and makes possible to work in a severe trancated Fock space for the renormalized Hamiltonian. Original works of Wegner in solid state physics has served us as the guiding principle in constructing the MSR scheme. The renormalized to the second order effective QED3+1 Hamiltonian on the light front is obtained. This Hamiltonian reproduces in |ee> sector the standard singlet-triplet splitting of positronium and recorves rotational symmetry of the canonical theory. The lowest and next-to-lowest energy states of positronium are almost independent on the cutoff when in both cases the 'same' (state and sector independent) counterterms are included. The electron (photon) mass counterterms are IR (collinear) finite if all diagrams to the second order, arising from the flow equations and normal-ordering Hamiltonian, are taken into account, and vary with UV cutoff in accordance with 1-loop renormalization group equations. Both approximations of perturbation theory and Fock space trancation are under the control and can be improved systematically within the proposed renormalization scheme.
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