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Hamiltonian Truncation Effective Theory

High Energy Physics - Theory 2022-08-10 v2 Strongly Correlated Electrons High Energy Physics - Lattice High Energy Physics - Phenomenology

Abstract

Hamiltonian truncation is a non-perturbative numerical method for calculating observables of a quantum field theory. The starting point for this method is to truncate the interacting Hamiltonian to a finite-dimensional space of states spanned by the eigenvectors of the free Hamiltonian H0H_0 with eigenvalues below some energy cutoff EmaxE_\text{max}. In this work, we show how to treat Hamiltonian truncation systematically using effective field theory methodology. We define the finite-dimensional effective Hamiltonian by integrating out the states above EmaxE_\text{max}. The effective Hamiltonian can be computed by matching a transition amplitude to the full theory, and gives corrections order by order as an expansion in powers of 1/Emax1/E_\text{max}. The effective Hamiltonian is non-local, with the non-locality controlled in an expansion in powers of H0/EmaxH_0/E_\text{max}. The effective Hamiltonian is also non-Hermitian, and we discuss whether this is a necessary feature or an artifact of our definition. We apply our formalism to 2D λϕ4\lambda \phi^4 theory, and compute the the leading 1/Emax21/E_\text{max}^2 corrections to the effective Hamiltonian. We show that these corrections non-trivially satisfy the crucial property of separation of scales. Numerical diagonalization of the effective Hamiltonian gives residual errors of order 1/Emax31/E_\text{max}^3, as expected by our power counting. We also present the power counting for 3D λϕ4\lambda \phi^4 theory and perform calculations that demonstrate the separation of scales in this theory.

Keywords

Cite

@article{arxiv.2110.08273,
  title  = {Hamiltonian Truncation Effective Theory},
  author = {Timothy Cohen and Kara Farnsworth and Rachel Houtz and Markus A. Luty},
  journal= {arXiv preprint arXiv:2110.08273},
  year   = {2022}
}

Comments

51 pages, 9 figures, v2: Clarifications and additional discussion added in response to referee reports. Conclusions unchanged

R2 v1 2026-06-24T06:55:44.639Z