Internal Excitations of Global Vortices. (arXiv:2107.02215v2 [hep-th] UPDATED)
<a href="http://arxiv.org/find/hep-th/1/au:+Blanco_Pillado_J/0/1/0/all/0/1">Jose J. Blanco-Pillado</a>, <a href="http://arxiv.org/find/hep-th/1/au:+Jimenez_Aguilar_D/0/1/0/all/0/1">Daniel Jim&#xe9;nez-Aguilar</a>, <a href="http://arxiv.org/find/hep-th/1/au:+Queiruga_J/0/1/0/all/0/1">Jose M. Queiruga</a>, <a href="http://arxiv.org/find/hep-th/1/au:+Urrestilla_J/0/1/0/all/0/1">Jon Urrestilla</a>

We investigate the spectrum of linearized excitations of global vortices in
$2+1$ dimensions. After identifying the existence of localized excitation
modes, we compute the decay time scale of the first two and compare the results
to the numerical evolution of the full non-linear equations. We show
numerically how the interaction of vortices with an external source of
radiation or other vortices can excite these modes dynamically. We then
simulate the formation of vortices in a phase transition and their interaction
with a thermal bath estimating the amplitudes of these modes in each case.
These numerical experiments indicate that even though, in principle, vortices
are capable of storing a large amount of energy in these internal excitations,
this does not seem to happen dynamically. We then explore the evolution of a
network of vortices in an expanding (2+1) dimensional background, in particular
in a radiation dominated universe. We find that vortices are still excited
after the course of the cosmological evolution but again the level of
excitation is very small. The extra energy in the vortices in these
cosmological simulations never exceeds the $1%$ level of the total mass of the
core of the vortex.

We investigate the spectrum of linearized excitations of global vortices in
$2+1$ dimensions. After identifying the existence of localized excitation
modes, we compute the decay time scale of the first two and compare the results
to the numerical evolution of the full non-linear equations. We show
numerically how the interaction of vortices with an external source of
radiation or other vortices can excite these modes dynamically. We then
simulate the formation of vortices in a phase transition and their interaction
with a thermal bath estimating the amplitudes of these modes in each case.
These numerical experiments indicate that even though, in principle, vortices
are capable of storing a large amount of energy in these internal excitations,
this does not seem to happen dynamically. We then explore the evolution of a
network of vortices in an expanding (2+1) dimensional background, in particular
in a radiation dominated universe. We find that vortices are still excited
after the course of the cosmological evolution but again the level of
excitation is very small. The extra energy in the vortices in these
cosmological simulations never exceeds the $1%$ level of the total mass of the
core of the vortex.

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