Abstract
AbstractAntisymmetric tensor fields are a compelling prediction of string theory. This makes them an interesting target for particle physics because antisymmetric tensors may couple to electromagnetic dipole moments, thus opening a possible discovery opportunity for string theory. The strongest constraints on electromagnetic dipole couplings would arise from couplings to electrons, where these couplings would contribute to Møller and Bhabha scattering. Previous measurements of Bhabha scattering constrain the couplings to $${\tilde{M}}_e m_C>7.1\times 10^4\,{\mathrm {GeV}}^2$$
M
~
e
m
C
>
7.1
×
10
4
GeV
2
, where $$m_C$$
m
C
is the mass of the antisymmetric tensor field and $${\tilde{M}}_e$$
M
~
e
is an effective mass scale appearing in the electromagnetic dipole coupling.
Funder
Shastri Indo-Canadian Institute
Mitacs
Natural Sciences and Engineering Research Council of Canada
Publisher
Springer Science and Business Media LLC
Subject
Physics and Astronomy (miscellaneous),Engineering (miscellaneous)
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