Improved precision calculation of the 0νββ contact term within chiral effective field theory
Improved precision calculation of the 0νββ contact term within chiral effective field theory
Neutrinoless double-beta (0νββ) decay is an as-yet unobserved nuclear process, which stands to provide crucial insights for model building beyond the Standard Model of particle physics. Its detection would simultaneously confirm the hypothesis that neutrinos are Majorana fermions, thus violating lepton-number conservation, and provide the first measurement of the absolute neutrino mass scale. This work aims to improve the estimation within chiral effective field theory of the so-called "contact term"for 0νββ decay, a short-range two-nucleon effect that is unaccounted for in traditional nuclear approaches to the process. We conduct a thorough review of the justifications for this contact term and the most precise computation of its size to date [gνNN=1.3(6) at renormalization point μ=mπ], whose precision is limited by a truncation to elastic intermediate hadronic states. We then perform an extension of this analysis to a subleading class of inelastic intermediate states that we characterize, delivering an updated figure for the contact coefficient [gνNN=1.4(3) at μ=mπ] with uncertainty reduced by half. Such ab initio nuclear results, especially with enhanced precision, show promise for the resolution of disagreements between estimates of 0ννββ from different many-body methods.
Goffrier, Graham Van
18877be8-d9be-4c90-a625-8f1c11b9cb84
31 March 2025
Goffrier, Graham Van
18877be8-d9be-4c90-a625-8f1c11b9cb84
Goffrier, Graham Van
(2025)
Improved precision calculation of the 0νββ contact term within chiral effective field theory.
Physical Review D, 111 (5), [055033].
(doi:10.1103/PhysRevD.111.055033).
Abstract
Neutrinoless double-beta (0νββ) decay is an as-yet unobserved nuclear process, which stands to provide crucial insights for model building beyond the Standard Model of particle physics. Its detection would simultaneously confirm the hypothesis that neutrinos are Majorana fermions, thus violating lepton-number conservation, and provide the first measurement of the absolute neutrino mass scale. This work aims to improve the estimation within chiral effective field theory of the so-called "contact term"for 0νββ decay, a short-range two-nucleon effect that is unaccounted for in traditional nuclear approaches to the process. We conduct a thorough review of the justifications for this contact term and the most precise computation of its size to date [gνNN=1.3(6) at renormalization point μ=mπ], whose precision is limited by a truncation to elastic intermediate hadronic states. We then perform an extension of this analysis to a subleading class of inelastic intermediate states that we characterize, delivering an updated figure for the contact coefficient [gνNN=1.4(3) at μ=mπ] with uncertainty reduced by half. Such ab initio nuclear results, especially with enhanced precision, show promise for the resolution of disagreements between estimates of 0ννββ from different many-body methods.
Text
PhysRevD.111.055033
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Accepted/In Press date: 3 March 2025
Published date: 31 March 2025
Identifiers
Local EPrints ID: 501446
URI: http://eprints.soton.ac.uk/id/eprint/501446
ISSN: 2470-0010
PURE UUID: bbc31c82-1717-4831-8a60-765a9087ee06
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Date deposited: 02 Jun 2025 16:34
Last modified: 22 Aug 2025 02:41
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Author:
Graham Van Goffrier
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