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The accuracy of QCD perturbation theory at high energies
We discuss the determination of the strong coupling $\alpha_\mathrm{\overline{MS}}^{}(m_\mathrm{Z})$ or equivalently the QCD $\Lambda$-parameter. Its determination requires the use of perturbation theory in $\alpha_s(\mu)$ in some scheme, $s$, and at some energy scale $\mu$. The higher the scale $\m...
| Autores principales: | , , , , , |
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| Lenguaje: | eng |
| Publicado: |
2016
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| Materias: | |
| Acceso en línea: | https://dx.doi.org/10.1103/PhysRevLett.117.182001 http://cds.cern.ch/record/2148145 |
| _version_ | 1780950416123494400 |
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| author | Dalla Brida, Mattia Fritzsch, Patrick Korzec, Tomasz Ramos, Alberto Sint, Stefan Sommer, Rainer |
| author_facet | Dalla Brida, Mattia Fritzsch, Patrick Korzec, Tomasz Ramos, Alberto Sint, Stefan Sommer, Rainer |
| author_sort | Dalla Brida, Mattia |
| collection | CERN |
| description | We discuss the determination of the strong coupling $\alpha_\mathrm{\overline{MS}}^{}(m_\mathrm{Z})$ or equivalently the QCD $\Lambda$-parameter. Its determination requires the use of perturbation theory in $\alpha_s(\mu)$ in some scheme, $s$, and at some energy scale $\mu$. The higher the scale $\mu$ the more accurate perturbation theory becomes, owing to asymptotic freedom. As one step in our computation of the $\Lambda$-parameter in three-flavor QCD, we perform lattice computations in a scheme which allows us to non-perturbatively reach very high energies, corresponding to $\alpha_s = 0.1$ and below. We find that perturbation theory is very accurate there, yielding a three percent error in the $\Lambda$-parameter, while data around $\alpha_s \approx 0.2$ is clearly insufficient to quote such a precision. It is important to realize that these findings are expected to be generic, as our scheme has advantageous properties regarding the applicability of perturbation theory. |
| id | cern-2148145 |
| institution | Organización Europea para la Investigación Nuclear |
| language | eng |
| publishDate | 2016 |
| record_format | invenio |
| spelling | cern-21481452023-08-11T03:52:17Zdoi:10.1103/PhysRevLett.117.182001http://cds.cern.ch/record/2148145engDalla Brida, MattiaFritzsch, PatrickKorzec, TomaszRamos, AlbertoSint, StefanSommer, RainerThe accuracy of QCD perturbation theory at high energiesParticle Physics - PhenomenologyWe discuss the determination of the strong coupling $\alpha_\mathrm{\overline{MS}}^{}(m_\mathrm{Z})$ or equivalently the QCD $\Lambda$-parameter. Its determination requires the use of perturbation theory in $\alpha_s(\mu)$ in some scheme, $s$, and at some energy scale $\mu$. The higher the scale $\mu$ the more accurate perturbation theory becomes, owing to asymptotic freedom. As one step in our computation of the $\Lambda$-parameter in three-flavor QCD, we perform lattice computations in a scheme which allows us to non-perturbatively reach very high energies, corresponding to $\alpha_s = 0.1$ and below. We find that perturbation theory is very accurate there, yielding a three percent error in the $\Lambda$-parameter, while data around $\alpha_s \approx 0.2$ is clearly insufficient to quote such a precision. It is important to realize that these findings are expected to be generic, as our scheme has advantageous properties regarding the applicability of perturbation theory.We discuss the determination of the strong coupling αMS¯(mZ) or, equivalently, the QCD Λ parameter. Its determination requires the use of perturbation theory in αs(μ) in some scheme s and at some energy scale μ. The higher the scale μ, the more accurate perturbation theory becomes, owing to asymptotic freedom. As one step in our computation of the Λ parameter in three-flavor QCD, we perform lattice computations in a scheme that allows us to nonperturbatively reach very high energies, corresponding to αs=0.1 and below. We find that (continuum) perturbation theory is very accurate there, yielding a 3% error in the Λ parameter, while data around αs≈0.2 are clearly insufficient to quote such a precision. It is important to realize that these findings are expected to be generic, as our scheme has advantageous properties regarding the applicability of perturbation theory.We discuss the determination of the strong coupling $\alpha_\mathrm{\overline{MS}}^{}(m_\mathrm{Z})$ or equivalently the QCD $\Lambda$-parameter. Its determination requires the use of perturbation theory in $\alpha_s(\mu)$ in some scheme, $s$, and at some energy scale $\mu$. The higher the scale $\mu$ the more accurate perturbation theory becomes, owing to asymptotic freedom. As one step in our computation of the $\Lambda$-parameter in three-flavor QCD, we perform lattice computations in a scheme which allows us to non-perturbatively reach very high energies, corresponding to $\alpha_s = 0.1$ and below. We find that (continuum) perturbation theory is very accurate there, yielding a three percent error in the $\Lambda$-parameter, while data around $\alpha_s \approx 0.2$ is clearly insufficient to quote such a precision. It is important to realize that these findings are expected to be generic, as our scheme has advantageous properties regarding the applicability of perturbation theory.arXiv:1604.06193DESY-16-053IFT-UAM-CSIC-16-029CERN-TH-2016-060TCDMATH-16-04WUB-16-00TCD-MATH-16-04DESY 16-053IFT-UAM-CSIC-16-029CERN-TH-2016-060TCDMATH 16-04WUB-16-00oai:cds.cern.ch:21481452016-04-21 |
| spellingShingle | Particle Physics - Phenomenology Dalla Brida, Mattia Fritzsch, Patrick Korzec, Tomasz Ramos, Alberto Sint, Stefan Sommer, Rainer The accuracy of QCD perturbation theory at high energies |
| title | The accuracy of QCD perturbation theory at high energies |
| title_full | The accuracy of QCD perturbation theory at high energies |
| title_fullStr | The accuracy of QCD perturbation theory at high energies |
| title_full_unstemmed | The accuracy of QCD perturbation theory at high energies |
| title_short | The accuracy of QCD perturbation theory at high energies |
| title_sort | accuracy of qcd perturbation theory at high energies |
| topic | Particle Physics - Phenomenology |
| url | https://dx.doi.org/10.1103/PhysRevLett.117.182001 http://cds.cern.ch/record/2148145 |
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