The asymptotic behavior of Lorentz-violating photon fields
Abstract
In this work, we derive the Newman-Penrose formalism of Maxwell's equations using two approaches: differential forms and intrinsic derivatives. Denoting (kAF)μ as kμ, with kμ=(kt,kr,0,0) in spherically symmetric spacetimes, we show that the expansion in r-1 fails to produce consistent, closed solutions due to the inability to separate Lorentz-violating (LV) phase factors, as the Lorentz-invariant (LI) null tetrad does not adapt to the LV wavefront. Moreover, with exact formal solutions, we demonstrate that the expansion is nonperturbative in the LV parameter k2 kt-kr. For r1/k2, higher powers of k2 dominate over lower powers, as the latter decay more rapidly with increasing r. Although the Coulomb mode φ1(r/r2) deviates from the LI expectation O(r-2) due to LV corrections, the leading outgoing radiation mode remains unaffected, i.e., φ2(r-1). Given the constraint |kAF|10-44GeV CMBLV-N, the three complex scalars φa (a=0,1,2) still obey the peeling theorem: φa(r(a-3)),~a=0,1,2 for large, finite distances.
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