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Exploring the Invisible Renormalon: Renormalization of the Heavy-Quark Kinetic Energy
Using the virial theorem of the heavy-quark effective theory, we show that the mixing of the operator for the heavy-quark kinetic energy with the identity operator is forbidden at the one-loop order by Lorentz invariance. This explains why such a mixing was not observed in several one-loop calculati...
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| Lenguaje: | eng |
| Publicado: |
1996
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| Acceso en línea: | https://dx.doi.org/10.1016/S0370-2693(96)01600-0 http://cds.cern.ch/record/313550 |
| _version_ | 1780890242196176896 |
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| author | Neubert, Matthias |
| author_facet | Neubert, Matthias |
| author_sort | Neubert, Matthias |
| collection | CERN |
| description | Using the virial theorem of the heavy-quark effective theory, we show that the mixing of the operator for the heavy-quark kinetic energy with the identity operator is forbidden at the one-loop order by Lorentz invariance. This explains why such a mixing was not observed in several one-loop calculations using regularization schemes with a Lorentz-invariant UV regulator, and why no UV renormalon singularity was found in the matrix elements of the kinetic operator in the bubble approximation (the ``invisible renormalon''). On the other hand, we show that the mixing is not protected in general by any symmetry, and it indeed occurs at the two-loop order. This implies that the parameter $\lambda_1^H$ of the heavy-quark effective theory is not directly a physical quantity, but requires a non-perturbative subtraction. |
| id | cern-313550 |
| institution | Organización Europea para la Investigación Nuclear |
| language | eng |
| publishDate | 1996 |
| record_format | invenio |
| spelling | cern-3135502023-03-14T17:12:18Zdoi:10.1016/S0370-2693(96)01600-0http://cds.cern.ch/record/313550engNeubert, MatthiasExploring the Invisible Renormalon: Renormalization of the Heavy-Quark Kinetic EnergyParticle Physics - PhenomenologyUsing the virial theorem of the heavy-quark effective theory, we show that the mixing of the operator for the heavy-quark kinetic energy with the identity operator is forbidden at the one-loop order by Lorentz invariance. This explains why such a mixing was not observed in several one-loop calculations using regularization schemes with a Lorentz-invariant UV regulator, and why no UV renormalon singularity was found in the matrix elements of the kinetic operator in the bubble approximation (the ``invisible renormalon''). On the other hand, we show that the mixing is not protected in general by any symmetry, and it indeed occurs at the two-loop order. This implies that the parameter $\lambda_1^H$ of the heavy-quark effective theory is not directly a physical quantity, but requires a non-perturbative subtraction.Using the virial theorem of the heavy-quark effective theory, we show that the mixing of the operator for the heavy-quark kinetic energy with the identity operator is forbidden at the one-loop order by Lorentz invariance. This explains why such a mixing was not observed in several one-loop calculations using regularization schemes with a Lorentz-invariant UV regulator, and why no UV renormalon singularity was found in the matrix elements of the kinetic operator in the bubble approximation (the ``invisible renormalon''). On the other hand, we show that the mixing is not protected in general by any symmetry, and it indeed occurs at the two-loop order. This implies that the parameter $\lambda_1~H$ of the heavy-quark effective theory is not directly a physical quantity, but requires a non-perturbative subtraction.Using the virial theorem of the heavy-quark effective theory, we show that the mixing of the operator for the heavy-quark kinetic energy with the identity operator is forbidden at the one-loop order by Lorentz invariance. This explains why such a mixing was not observed in several one-loop calculations using regularization schemes with a Lorentz-invariant UV regulator, and why no UV renormalon singularity was found in the matrix elements of the kinetic operator in the bubble approximation (the ``invisible renormalon''). On the other hand, we show that the mixing is not protected in general by any symmetry, and it indeed occurs at the two-loop order. This implies that the parameter $\lambda_1~H$ of the heavy-quark effective theory is not directly a physical quantity, but requires a non-perturbative subtraction.Using the virial theorem of the heavy-quark effective theory, we show that the mixing of the operator for the heavy-quark kinetic energy with the identity operator is forbidden at the one-loop order by Lorentz invariance. This explains why such a mixing was not observed in several one-loop calculations using regularization schemes with a Lorentz-invariant UV regulator, and why no UV renormalon singularity was found in the matrix elements of the kinetic operator in the bubble approximation (the ``invisible renormalon''). On the other hand, we show that the mixing is not protected in general by any symmetry, and it indeed occurs at the two-loop order. This implies that the parameter $\lambda_1~H$ of the heavy-quark effective theory is not directly a physical quantity, but requires a non-perturbative subtraction.Using the virial theorem of the heavy-quark effective theory, we show that the mixing of the operator for the heavy-quark kinetic energy with the identity operator is forbidden at the one-loop order by Lorentz invariance. This explains why such a mixing was not observed in several one-loop calculations using regularization schemes with a Lorentz-invariant UV regulator, and why no UV renormalon singularity was found in the matrix elements of the kinetic operator in the bubble approximation (the “invisible renormalon”). On the other hand, we show that the mixing is not protected in general by any symmetry, and it indeed occurs at the two-loop order. This implies that the parameter λ 1 H of the heavy-quark effective theory is not directly a physical quantity, but requires a non-perturbative subtraction.hep-ph/9610471CERN-TH-96-282CERN-TH-96-282oai:cds.cern.ch:3135501996-10-24 |
| spellingShingle | Particle Physics - Phenomenology Neubert, Matthias Exploring the Invisible Renormalon: Renormalization of the Heavy-Quark Kinetic Energy |
| title | Exploring the Invisible Renormalon: Renormalization of the Heavy-Quark Kinetic Energy |
| title_full | Exploring the Invisible Renormalon: Renormalization of the Heavy-Quark Kinetic Energy |
| title_fullStr | Exploring the Invisible Renormalon: Renormalization of the Heavy-Quark Kinetic Energy |
| title_full_unstemmed | Exploring the Invisible Renormalon: Renormalization of the Heavy-Quark Kinetic Energy |
| title_short | Exploring the Invisible Renormalon: Renormalization of the Heavy-Quark Kinetic Energy |
| title_sort | exploring the invisible renormalon: renormalization of the heavy-quark kinetic energy |
| topic | Particle Physics - Phenomenology |
| url | https://dx.doi.org/10.1016/S0370-2693(96)01600-0 http://cds.cern.ch/record/313550 |
| work_keys_str_mv | AT neubertmatthias exploringtheinvisiblerenormalonrenormalizationoftheheavyquarkkineticenergy |