Abstract
We explore the convergence of the light-front coupled-cluster (LFCC) method in the context of two-dimensional quenched scalar Yukawa theory. This theory is simple enough for higher-order LFCC calculations to be relatively straightforward. The quenching is to maintain stability; the spectrum of the full theory with pair creation and annihilation is unbounded from below. The basic interaction in the quenched theory is only emission and absorption of a neutral scalar by the complex scalar. The LFCC method builds the eigenstate with one complex scalar and a cloud of neutrals from a valence state that is just the complex scalar and the action of an exponentiated operator that creates neutrals. The lowest order LFCC operator creates one; we add the next order, a term that creates two. At this order there is a direct contribution to the wave function for two neutrals and one complex scalar and additional contributions to all higher Fock wave functions from the exponentiation. Results for the lowest order and this new second-order approximation are compared with those obtained with standard Fock-state expansions. The LFCC approach is found to allow representation of the eigenstate with far fewer functions than the number of wave functions required in a converged Fock-state expansion.
Highlights
The calculation of the bound states for a given quantum field theory is an inherently nonperturbative problem
We have developed the light-front coupled-cluster (LFCC) method [10]
We have shown that the LFCC approximation provides an efficient representation of a massive eigenstate in quenched scalar Yukawa theory
Summary
The calculation of the bound states for a given quantum field theory is an inherently nonperturbative problem. The complement projection 1 − Pv is restricted to the lowest set of Fock sectors necessary to have enough equations to solve for the functions that define T This means that the LFCC method is not variational; the effective Hamiltonian P− is not Hermitian, and the truncated projections are not. An explicit example of this appears in an application to φ4 theory [12], where the solution for the lowest-order approximation for T does not extend beyond a certain coupling strength This is likely due to the restriction of the valence state to a single constituent in a regime near the critical coupling where all Fock sectors should contribute strongly.
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