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Main Authors: Ayala, César, Castro-Arriaza, Camilo, Cvetič, Gorazd
Format: Preprint
Published: 2023
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Online Access:https://arxiv.org/abs/2312.13134
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author Ayala, César
Castro-Arriaza, Camilo
Cvetič, Gorazd
author_facet Ayala, César
Castro-Arriaza, Camilo
Cvetič, Gorazd
contents Approximate knowledge of the renormalon structure of the Bjorken polarised sum rule (BSR) ${\overline Γ}_1^{\rm p-n}(Q^2)$ leads to the corresponding BSR characteristic function that allows us to evaluate the leading-twist part of BSR. In our previous work \cite{pPLB}, this evaluation (resummation) was performed using perturbative QCD (pQCD) coupling $a(Q^2) \equiv α_s(Q^2)/π$ in specific renormalisation schemes. In the present paper, we continue this work, by using instead holomorphic couplings [$a(Q^2) \mapsto {\mathcal A}(Q^2)$] that have no Landau singularities and thus require, in contrast to the pQCD case, no regularisation of the resummation formula. The $D=2$ and $D=4$ terms are included in the Operator Product Expansion (OPE) of inelastic BSR, and fits are performed to the available experimental data in a specific interval $(Q^2_{\rm min},Q^2_{\rm max})$ where $ Q^2_{\rm max}=4.74 \ {\rm GeV}^2$. We needed relatively high $Q^2_{\rm min} \approx 1.7 \ {\rm GeV}^2$ in the pQCD case since the pQCD coupling $a(Q^2)$ has Landau singularities at $Q^2 \lesssim 1 \ {\rm GeV}^2$. Now, when holomorphic (AQCD) couplings ${\mathcal A}(Q^2)$ are used, no such problems occur: for the $3 δ$AQCD and $2 δ$AQCD variants the preferred values are $Q^2_{\rm min} \approx 0.6 \ {\rm GeV}^2$. The preferred values of $α_s$ in general cannot be unambiguously extracted, due to large uncertainties of the experimental BSR data. At a fixed value of $α_s^{\overline {\rm MS}}(M_Z^2)$, the values of the $D=2$ and $D=4$ residue parameters are determined in all cases, with the corresponding uncertainties.
format Preprint
id arxiv_https___arxiv_org_abs_2312_13134
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Renormalon-based resummation of Bjorken polarised sum rule in holomorphic QCD
Ayala, César
Castro-Arriaza, Camilo
Cvetič, Gorazd
High Energy Physics - Phenomenology
Approximate knowledge of the renormalon structure of the Bjorken polarised sum rule (BSR) ${\overline Γ}_1^{\rm p-n}(Q^2)$ leads to the corresponding BSR characteristic function that allows us to evaluate the leading-twist part of BSR. In our previous work \cite{pPLB}, this evaluation (resummation) was performed using perturbative QCD (pQCD) coupling $a(Q^2) \equiv α_s(Q^2)/π$ in specific renormalisation schemes. In the present paper, we continue this work, by using instead holomorphic couplings [$a(Q^2) \mapsto {\mathcal A}(Q^2)$] that have no Landau singularities and thus require, in contrast to the pQCD case, no regularisation of the resummation formula. The $D=2$ and $D=4$ terms are included in the Operator Product Expansion (OPE) of inelastic BSR, and fits are performed to the available experimental data in a specific interval $(Q^2_{\rm min},Q^2_{\rm max})$ where $ Q^2_{\rm max}=4.74 \ {\rm GeV}^2$. We needed relatively high $Q^2_{\rm min} \approx 1.7 \ {\rm GeV}^2$ in the pQCD case since the pQCD coupling $a(Q^2)$ has Landau singularities at $Q^2 \lesssim 1 \ {\rm GeV}^2$. Now, when holomorphic (AQCD) couplings ${\mathcal A}(Q^2)$ are used, no such problems occur: for the $3 δ$AQCD and $2 δ$AQCD variants the preferred values are $Q^2_{\rm min} \approx 0.6 \ {\rm GeV}^2$. The preferred values of $α_s$ in general cannot be unambiguously extracted, due to large uncertainties of the experimental BSR data. At a fixed value of $α_s^{\overline {\rm MS}}(M_Z^2)$, the values of the $D=2$ and $D=4$ residue parameters are determined in all cases, with the corresponding uncertainties.
title Renormalon-based resummation of Bjorken polarised sum rule in holomorphic QCD
topic High Energy Physics - Phenomenology
url https://arxiv.org/abs/2312.13134