2018
DOI: 10.1007/jhep06(2018)024
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Magnetically charged calorons with non-trivial holonomy

Abstract: Instantons in pure Yang-Mills theories on partially periodic space R 3 × S 1 are usually called calorons. The background periodicity brings on characteristic features of calorons such as nontrivial holonomy, which plays an essential role for confinement/deconfinement transition in pure Yang-Mills gauge theory. For the case of gauge group S U(2), calorons can be interpreted as composite objects of two constituent "monopoles" with opposite magnetic charges. There are often the cases that the two monopole charges… Show more

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Cited by 5 publications
(6 citation statements)
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“…Since the Skyrme-instanton boundary condition (65) for non-zero µ breaks the gauge symmetry to U (1), there may be a relationship with the U (1)gauged skyrmions found in [42], which also exhibit an axial symmetry, in addition to a non-zero dipole moment, which is similar to the interpretation of (1, 1)-calorons as two oppositely charged magnetic monopoles [26]. Another axially symmetric caloron appears explicitly in [56]. This caloron is possibly more interesting as it has a mixture of instanton and magnetic charge -it is a (2, 1)-caloron.…”
Section: Summary and Open Problemsmentioning
confidence: 59%
See 1 more Smart Citation
“…Since the Skyrme-instanton boundary condition (65) for non-zero µ breaks the gauge symmetry to U (1), there may be a relationship with the U (1)gauged skyrmions found in [42], which also exhibit an axial symmetry, in addition to a non-zero dipole moment, which is similar to the interpretation of (1, 1)-calorons as two oppositely charged magnetic monopoles [26]. Another axially symmetric caloron appears explicitly in [56]. This caloron is possibly more interesting as it has a mixture of instanton and magnetic charge -it is a (2, 1)-caloron.…”
Section: Summary and Open Problemsmentioning
confidence: 59%
“…Before we prove the existence of the bound (57), we shall first confirm that C(α) given by (58) is real. Indeed, we clearly have κ 0 > 0 by (37), and (56) shows that the numerator of C(α) 2 is positive. For the denominator, we have by (56) that Thus comparing this with (58), we see that C(α) 2 > 0, so C(α) ∈ R. Now consider the quadratic form…”
Section: Theoremmentioning
confidence: 85%
“…The class of calorons with non-trivial holonomy are crucial in the analysis for the confinement/deconfinement phase transition of quarks in QCD [44,45,46,47,48,49,50,51,52]. The higher charge generalization for the non-trivial holonomy calorons is quite restricted except for the cases of instanton charge two [33,34,35,36]. This situation is reflecting the fact that the introduction of non-trivial holonomy in the Nahm data is extremely complicated problem, i.e., it is hard to construct the corresponding Nahm data.…”
Section: Discussionmentioning
confidence: 99%
“…Here we give an overview to these examples. The simplest case of N = 2 calorons with axial symmetry are the Harrington-Shepard type 2calorons [26,34], whose analytic description of the gauge fields is given in [35]. For the case of non-trivial holonomy, the Nahm data of the charge 2-calorons with axial symmetry are considered in [33,34,36,37], employing the BPS 2-monopole data as their bulk data, which are given in trigonometric functions.…”
Section: Work Previously Studied On Symmetric Caloronsmentioning
confidence: 99%
“…In this section we shall reproduce the KvBLL calorons from their Nahm data, that is, we shall apply the Nahm transform explicitly. This was also reviewed recently in [45] using a different, but equivalent formulation of the Nahm transform. Our calculation is most similar to that of [33].…”
Section: A Kvbll Caloronsmentioning
confidence: 99%