Feynman-Hellmann approach to transition matrix elements and quasi-degenerate energy states

Batelaan, M.; Can, K. U.; Zanotti, J. M.; Horsley, R.; Young, R. D.; QCDSF-UKQCD-CSSM Collaboration; Stüben, H.; Nakamura, Y.; Schierholz, Gerrit; Rakow, P. E. L.

Preprint

PUBDB-2023-02965

Feynman-Hellmann approach to transition matrix elements and quasi-degenerate energy states

Batelaan, M. ; Can, K. U. ; Horsley, R. (Corresponding author)Extern* ; Nakamura, Y. ; Rakow, P. E. L. ; Schierholz, G.DESY* ; Stüben, H. ; Young, R. D. ; Zanotti, J. M. ; QCDSF-UKQCD-CSSM Collaboration (Collaboration author)

2023

[10.3204/PUBDB-2023-02965]

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Please use a persistent id in citations: doi:10.3204/PUBDB-2023-02965

Report No.: ADP-23-12/T1221; DESY-23-059; Liverpool LTH 1340; arXiv:2305.05491

Abstract: The Feynman-Hellmann approach to computing matrix elements in lattice QCD by first adding a perturbing operator to the action is described using the transition matrix and the Dyson expansion formalism. This perturbs the energies in the two-point baryon correlation function, from which the matrix element can be obtained. In particular at leading order in the perturbation we need to diagonalise a matrix of near-degenerate energies. While the method is general for all hadrons, we apply it here to a study of a Sigma to Nucleon baryon transition vector matrix element.

Keyword(s): higher-order, 0 ; baryon, correlation function ; lattice field theory ; perturbation ; hadron ; nucleon