Thermal modification of K1(1270) π+π-K+ in a hot hadronic medium
Abstract
We study the thermal modification of the exclusive decay K1+(1270) π+π-K+ in a hot hadronic medium. The decay amplitude is constructed from effective hadronic interactions dominated by the - and K*-pole contributions, which enables a Dalitz-level analysis of the three-body decay in medium. Thermal effects associated with partial chiral-symmetry restoration are incorporated through a phenomenological interpolation toward vector--axial-vector degeneracy near the chiral crossover. As the temperature increases, the reduction of the parent K1 mass strongly compresses the available three-body phase space, leading to substantial deformation of the Dalitz distribution and invariant-mass spectra, as well as to a pronounced suppression of K1π+π-K+(T). As a further step toward future experimental comparison, we introduce normalized shape observables that quantify the thermal evolution of the K*-dominated π K region, the upper-edge weight of the ππ spectrum, and the compactification of the Dalitz population. The dominant effect identified in the present framework is therefore kinematic: thermal phase-space reduction in the strange axial-vector channel. These results suggest that the exclusive K1(1270) channel may provide a useful qualitative probe of in-medium strange axial-vector dynamics near the pseudocritical region.
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