S. M. Morozov scite author profile

Propagators of the diagonal and the off-diagonal gluons are studied numerically in the Maximal Abelian gauge of SU(2) lattice gauge theory. It is found that in the infrared region the propagator of the diagonal gluon is strongly enhanced in comparison with the off-diagonal one. The enhancement factor is about 50 at our smallest momentum 325 MeV. We have also applied various fits to the propagator formfactors.

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The International Large Detector: Letter of Intent

Abe¹,

Schuwalow²,

Yamauchi³

et al. 2010

106

128

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Lattice gauge fields topology uncovered by quaternionicσ-model embedding

Gubarev

Morozov

2005

Phys. Rev. D

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We investigate SU(2) gauge fields topology using new approach, which exploits the well known connection between SU(2) gauge theory and quaternionic projective σ-models and allows to formulate the topological charge density entirely in terms of σ-model fields. The method is studied in details and for thermalized vacuum configurations is shown to be compatible with overlap-based definition. We confirm that the topological charge is distributed in localized four dimensional regions which, however, are not compatible with instantons. Topological density bulk distribution is investigated at different lattice spacings and is shown to possess some universal properties.

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Calorons and dyons at the thermal phase transition analyzed by overlap fermions

et al. 2007

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In a pilot study, we use the topological charge density defined by the eigenmodes of the overlap Dirac operator (with ultraviolet filtering by mode-truncation) to search for lumps of topological charge in SU (2) pure gauge theory. Augmenting this search with periodic and antiperiodic temporal boundary conditions for the overlap fermions, we demonstrate that the lumps can be classified either as calorons or as separate caloron constituents (dyons). Inside the topological charge clusters the (smeared) Polyakov loop is found to show the typical profile characteristic for calorons and dyons. This investigation, motivated by recent caloron/dyon model studies, is performed at the deconfinement phase transition for SU (2) gluodynamics on 20 3 × 6 lattices described by the tadpole improved Lüscher-Weisz action. The transition point has been carefully located. As a necessary condition for the caloron/dyon detection capability, we check that the LW action, in contrast to the Wilson action, generates lattice ensembles, for which the overlap Dirac eigenvalue spectrum smoothly behaves under smearing and under the change of the boundary conditions.

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Probing the finite temperature phase transition withNf=2nonperturbatively improved Wilson fermions

et al. 2010

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S. M. Morozov

Abelian dominance and gluon propagators in the maximally Abelian gauge of SU(2) lattice gauge theory

The International Large Detector: Letter of Intent

Lattice gauge fields topology uncovered by quaternionicσ-model embedding

Calorons and dyons at the thermal phase transition analyzed by overlap fermions

Probing the finite temperature phase transition withNf=2nonperturbatively improved Wilson fermions

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