Abstract
We apply the BPS Lagrangian method to derive BPS equations of monopole and dyon in the SU2 Yang-Mills-Higgs model, Nakamula-Shiraishi models, and their generalized versions. We argue that, by identifying the effective fields of scalar field, f, and of time-component gauge field, j, explicitly by j=βf with β being a real constant, the usual BPS equations for dyon can be obtained naturally. We validate this identification by showing that both Euler-Lagrange equations for f and j are identical in the BPS limit. The value of β is bounded to β<1 due to reality condition on the resulting BPS equations. In the Born-Infeld type of actions, namely, Nakamula-Shiraishi models and their generalized versions, we find a new feature that, by adding infinitesimally the energy density up to a constant 4b2, with b being the Born-Infeld parameter, it might turn monopole (dyon) to antimonopole (antidyon) and vice versa. In all generalized versions there are additional constraint equations that relate the scalar-dependent couplings of scalar and of gauge kinetic terms or G and w, respectively. For monopole the constraint equation is G=w-1, while for dyon it is wG-β2w=1-β2 which further gives lower bound to G as such G≥2β1-β2. We also write down the complete square-forms of all effective Lagrangians.
Highlights
Monopole has been known to exist in nonabelian gauge theory
The exact solutions were given by Prasad and Sommerfiled in [5] by taking some limit where V → 0. These solutions were proved by Bogomolnyi in [6] to be solutions of the first-order differential equations which turn out to be closely related to the study of supersymmetric system [7]
We have shown that the BPS Lagrangian method, which was used before in [16] for BPS vortex, can be applied to the case of BPS monopole and dyon in SU(2) Yang-MillsHiggs model (9)
Summary
Monopole has been known to exist in nonabelian gauge theory. One of the main developments was given by ’t Hooft in [1] and in parallel with a work by Polyakov in [2], in which he showed that monopole could arise as soliton in a YangMills-Higgs theory, without introducing Dirac’s string [3], by spontaneously breaking the symmetry of SO(3) gauge group into U(1) gauge group. We would like to derive the well-known BPS equations of monopole and dyon in the SU(2) YangMills-Higgs model and their Born-Infeld type extensions, which we shall call them Nakamula-Shiraishi models, using a procedure called BPS Lagrangian method developed in [16]. We extend those models to their generalized versions by adding scalar-dependent couplings to each of the kinetic terms and derive the BPS equations for monopole and dyon.
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