Quaternions and Small Lorentz Groups in Noncommutative Electrodynamics

Non-linear electrodynamics arising in the frames of field theories in noncommutative space-time is examined on the base of quaternion formalism. The problem of form-invariance of the corresponding nonlinear constitutive relations governed by six noncommutativity parameters

\theta_{kl}

or quaternion \underline{K} = \underline{\theta} - i \underline{\epsilon} is explored in detail. Two Abelian 2-parametric small groups, SO(2) \otimes O(1.1) or T_{2}, depending on invariant length \underline{K}^{2}\neq 0 or \underline{K}^{2}= 0 respectively, have been found. The way to interpret both small groups in physical terms consists in factorizing corresponding Lorentz transformations into Euclidean rotations and Lorentzian boosts. In the context of general study of various dual symmetries in noncommutative field theory, it is demonstrated explicitly that the nonlinear constitutive equations under consideration are not invariant under continuous dual rotations, instead only invariance under discrete dual transformation exists.

Note:

8 pages

electromagnetic field: noncommutative
field theory: noncommutative
space-time: noncommutative
transformation: Lorentz
duality: transformation
group: Lorentz
quaternion
Maxwell equation
spinor
SO(2)

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