arXiv : Consistency checks for two-body finite-volume matrix elements: Conserved currents and bound states

Briceño, Raúl A.; Hansen, Maxwell T.; Jackura, Andrew W.

doi:10.1103/PhysRevD.100.114505

Article
Report number	arXiv:1909.10357 ; JLAB-THY-19-3040 ; CERN-TH-2019-149
Title	Consistency checks for two-body finite-volume matrix elements: Conserved currents and bound states
Author(s)	Briceño, Raúl A. (Jefferson Lab ; Old Dominion U.) ; Hansen, Maxwell T. (CERN) ; Jackura, Andrew W. (Jefferson Lab ; Old Dominion U.)
Publication	2019-12-06
Imprint	2019-09-23
Number of pages	17
Note	20 pages, 5 figures
In:	Phys. Rev. D 100 (2019) 114505
DOI	10.1103/PhysRevD.100.114505
Subject category	nucl-th ; Nuclear Physics - Theory ; hep-ph ; Particle Physics - Phenomenology ; hep-lat ; Particle Physics - Lattice
Abstract	Recently, a framework has been developed to study form factors of two-hadron states probed by an external current. The method is based on relating finite-volume matrix elements, computed using numerical lattice QCD, to the corresponding infinite-volume observables. As the formalism is complicated, it is important to provide non-trivial checks on the final results and also to explore limiting cases in which more straightforward predications may be extracted. In this work we provide examples on both fronts. First, we show that, in the case of a conserved vector current, the formalism ensures that the finite-volume matrix element of the conserved charge is volume-independent and equal to the total charge of the two-particle state. Second, we study the implications for a two-particle bound state. We demonstrate that the infinite-volume limit reproduces the expected matrix element and derive the leading finite-volume corrections to this result for a scalar current. Finally, we provide numerical estimates for the expected size of volume effects in future lattice QCD calculations of the deuteron's scalar charge. We find that these effects completely dominate the infinite-volume result for realistic lattice volumes and that applying the present formalism, to analytically remove an infinite-series of leading volume corrections, is crucial to reliably extract the infinite-volume charge of the state.
Copyright/License	preprint: (License: arXiv nonexclusive-distrib 1.0) publication: © 2019-2025 authors (License: CC-BY-4.0)

$Analytic structure of $\Mc$ on the first Riemann sheet in the complex $s$-plane. Bound-state poles lie below two-particle threshold.$ $Plot of $q^{\star}\cot\delta(q^{\star})$ and $-\sqrt{-q^{\star2}}$ as a function of $q^{\star2}$, in units of $\mev^2$, for the effective range expansion, Eq.~\eqref{eq:ERE}, using the scattering length and effective range for the $pn$-system in $^{3}S_{1}$. The vertical dashed line indicates the deuteron, with binding momentum $\kappa_{\textrm{B}} \sim 45.58$ MeV.$ $(a) Representation of (left) the $\2+\Jc\to\2$ amplitude with initial and final energy-momentum given by $P_i$ and $P_f$, respectively, leading to a current-induced momentum transfer of $Q^2 = -(P_f - P_i)^2$, as well as (right) the $\2 \to \2$ scattering amplitude with energy-momentum $P$. (b) Definition of $\Wc_{\df}$ where the long-range terms of a current probing an external leg are removed. (c) Triangle diagram leading to important singularities in $\Wc_{\df}$.$ Show more plots

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Record created 2019-09-25, last modified 2023-10-04

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