Superconducting Cosmic Strings: Difference between revisions

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|OIRCounterpart        = --
|OIRCounterpart        = --
|XrayCounterpart        = --
|XrayCounterpart        = --
|GammarayCounterpart    = GRB <br\> if jet aligned
|GammarayCounterpart    = GRB <br/> if jet aligned
|GWCounterpart          = Yes
|GWCounterpart          = Yes
|NeutrinoCounterpart    = Yes
|NeutrinoCounterpart    = Yes
|References            = **need to add: http://adsabs.harvard.edu/abs/2015AASP....5...43Z to main paper, https://arxiv.org/pdf/1807.01976.pdf
|References            = http://adsabs.harvard.edu/abs/2015AASP....5...43Z, http://adsabs.harvard.edu/cgi-bin/bib_query?arXiv:1807.01976, http://adsabs.harvard.edu/cgi-bin/bib_query?arXiv:0802.0711
 
|Comments              = High energy cosmic rays are also expected.
|Comments              = High energy cosmic rays are also expected.
}}
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== Model Description ==
== Model Description ==


To be filled in with updated draft
A cosmic string becomes superconducting when coupled with electromagnetism; achievable through the unbroken symmetry of an extra Higgs field in the formation of the string. Various mechanisms have been considered in which superconducting cosmic strings may produce an FRB, such as: string oscillations, the collisions of string structures (cusps and kinks), and the interaction of a current-carrying loop in the magnetic field of a galaxy. In the last scenario listed, the event rate of FRBs indicates a loop size consistent with strings formed during the radiation era. The emission from superconducting cosmic strings is linearly polarized - an intrinsic signature that is independent of frequency and is not affected by polarization via the ISM.  Expected counterparts are other EM counterparts - specifically, GRBs, cosmic rays, and neutrinos - and GWs.


== Observational Constraints ==
== Observational Constraints ==


To be filled in with updated draft
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Latest revision as of 06:30, 11 October 2018





Summary Table
Category Progenitor Type Energy Mechanism Emission Mechanism Counterparts References Brief Comments
LF Radio HF Radio Microwave Terahertz Optical/IR X-rays Gamma-rays Gravitational Waves Neutrinos
Other Superconducting Cosmic Strings Single Cusp decay -- Yes -- -- -- -- -- GRB
if jet aligned
Yes Yes http://adsabs.harvard.edu/abs/2015AASP....5...43Z, http://adsabs.harvard.edu/cgi-bin/bib_query?arXiv:1807.01976, http://adsabs.harvard.edu/cgi-bin/bib_query?arXiv:0802.0711 High energy cosmic rays are also expected.

Definitions: LF Radio (3 MHz to 3 GHz); HF Radio (3 GHz to 30 GHz); Microwave (30 to 300 GHz)


Model Description

A cosmic string becomes superconducting when coupled with electromagnetism; achievable through the unbroken symmetry of an extra Higgs field in the formation of the string. Various mechanisms have been considered in which superconducting cosmic strings may produce an FRB, such as: string oscillations, the collisions of string structures (cusps and kinks), and the interaction of a current-carrying loop in the magnetic field of a galaxy. In the last scenario listed, the event rate of FRBs indicates a loop size consistent with strings formed during the radiation era. The emission from superconducting cosmic strings is linearly polarized - an intrinsic signature that is independent of frequency and is not affected by polarization via the ISM. Expected counterparts are other EM counterparts - specifically, GRBs, cosmic rays, and neutrinos - and GWs.

Observational Constraints

-