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Vacuum correlators at short distances from lattice QCD

Non-perturbatively computing the hadronic vacuum polarization at large photon virtualities and making contact with perturbation theory enables a precision determination of the electromagnetic coupling at the Z pole, which enters global electroweak fits. In order to achieve this goal ab initio using...

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Autores principales: Cè, Marco, Harris, Tim, Meyer, Harvey B., Toniato, Arianna, Török, Csaba
Lenguaje:eng
Publicado: 2021
Materias:
Acceso en línea:https://dx.doi.org/10.1007/JHEP12(2021)215
http://cds.cern.ch/record/2775807
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author Cè, Marco
Harris, Tim
Meyer, Harvey B.
Toniato, Arianna
Török, Csaba
author_facet Cè, Marco
Harris, Tim
Meyer, Harvey B.
Toniato, Arianna
Török, Csaba
author_sort Cè, Marco
collection CERN
description Non-perturbatively computing the hadronic vacuum polarization at large photon virtualities and making contact with perturbation theory enables a precision determination of the electromagnetic coupling at the Z pole, which enters global electroweak fits. In order to achieve this goal ab initio using lattice QCD, one faces the challenge that, at the short distances which dominate the observable, discretization errors are hard to control. Here we address challenges of this type with the help of static screening correlators in the high-temperature phase of QCD, yet without incurring any bias. The idea is motivated by the observations that (a) the cost of high-temperature simulations is typically much lower than their vacuum counterpart, and (b) at distances x$_{3}$ far below the inverse temperature 1/T, the operator-product expansion guarantees the thermal correlator of two local currents to deviate from the vacuum correlator by a relative amount that is power-suppressed in (x$_{3}$T). The method is first investigated in lattice perturbation theory, where we point out the appearance of an O(a$^{2}$ log(1/a)) lattice artifact in the vacuum polarization with a prefactor that we calculate. It is then applied to non-perturbative lattice QCD data with two dynamical flavors of quarks. Our lattice spacings range down to 0.049 fm for the vacuum simulations and down to 0.033 fm for the simulations performed at a temperature of 250 MeV.
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institution Organización Europea para la Investigación Nuclear
language eng
publishDate 2021
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spelling cern-27758072023-10-04T07:34:21Zdoi:10.1007/JHEP12(2021)215http://cds.cern.ch/record/2775807engCè, MarcoHarris, TimMeyer, Harvey B.Toniato, AriannaTörök, CsabaVacuum correlators at short distances from lattice QCDhep-phParticle Physics - Phenomenologyhep-latParticle Physics - LatticeNon-perturbatively computing the hadronic vacuum polarization at large photon virtualities and making contact with perturbation theory enables a precision determination of the electromagnetic coupling at the Z pole, which enters global electroweak fits. In order to achieve this goal ab initio using lattice QCD, one faces the challenge that, at the short distances which dominate the observable, discretization errors are hard to control. Here we address challenges of this type with the help of static screening correlators in the high-temperature phase of QCD, yet without incurring any bias. The idea is motivated by the observations that (a) the cost of high-temperature simulations is typically much lower than their vacuum counterpart, and (b) at distances x$_{3}$ far below the inverse temperature 1/T, the operator-product expansion guarantees the thermal correlator of two local currents to deviate from the vacuum correlator by a relative amount that is power-suppressed in (x$_{3}$T). The method is first investigated in lattice perturbation theory, where we point out the appearance of an O(a$^{2}$ log(1/a)) lattice artifact in the vacuum polarization with a prefactor that we calculate. It is then applied to non-perturbative lattice QCD data with two dynamical flavors of quarks. Our lattice spacings range down to 0.049 fm for the vacuum simulations and down to 0.033 fm for the simulations performed at a temperature of 250 MeV.Non-perturbatively computing the hadronic vacuum polarization at large photon virtualities and making contact with perturbation theory enables a precision determination of the electromagnetic coupling at the $Z$ pole, which enters global electroweak fits. In order to achieve this goal ab initio using lattice QCD, one faces the challenge that, at the short distances which dominate the observable, discretization errors are hard to control. Here we address challenges of this type with the help of static screening correlators in the high-temperature phase of QCD, yet without incurring any bias. The idea is motivated by the observations that (a) the cost of high-temperature simulations is typically much lower than their vacuum counterpart, and (b) at distances $x_3$ far below the inverse temperature $1/T$, the operator-product expansion guarantees the thermal correlator of two local currents to deviate from the vacuum correlator by a relative amount that is power-suppressed in $(x_3\:T)$. The method is first investigated in lattice perturbation theory, where we point out the appearance of an O$(a^2 \log(1/a))$ lattice artifact in the vacuum polarization with a prefactor that we calculate. It is then applied to non-perturbative lattice QCD data with two dynamical flavors of quarks. Our lattice spacings range down to 0.049 fm for the vacuum simulations and down to 0.033 fm for the simulations performed at a temperature of 250 MeV.arXiv:2106.15293MITP/21-032CERN-TH-2021-100oai:cds.cern.ch:27758072021-06-29
spellingShingle hep-ph
Particle Physics - Phenomenology
hep-lat
Particle Physics - Lattice
Cè, Marco
Harris, Tim
Meyer, Harvey B.
Toniato, Arianna
Török, Csaba
Vacuum correlators at short distances from lattice QCD
title Vacuum correlators at short distances from lattice QCD
title_full Vacuum correlators at short distances from lattice QCD
title_fullStr Vacuum correlators at short distances from lattice QCD
title_full_unstemmed Vacuum correlators at short distances from lattice QCD
title_short Vacuum correlators at short distances from lattice QCD
title_sort vacuum correlators at short distances from lattice qcd
topic hep-ph
Particle Physics - Phenomenology
hep-lat
Particle Physics - Lattice
url https://dx.doi.org/10.1007/JHEP12(2021)215
http://cds.cern.ch/record/2775807
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AT torokcsaba vacuumcorrelatorsatshortdistancesfromlatticeqcd