The role of K^*_0(1430) in D->PK and \tau->KP\nu_\tau decays

TL;DR

This paper investigates the influence of the scalar meson K^*_0(1430) on D and tau decays involving kaons and pions, using resonance dominance and fitting decay amplitudes to experimental data.

Contribution

It introduces a resonance-based model for scalar form factors in D and tau decays, incorporating the K^*_0(1430) meson and analyzing its impact on decay spectra and rates.

Findings

Final state interactions improve decay data agreement.

Bounds on scalar form factor parameters are extracted.

K^*_0(1430) dominates tau->K eta' decay spectrum.

Abstract

We consider the scalar form factor in the weak current matrix element <P K| j_\mu |0>, P =\pi,\eta,\eta'. It obtains the contributions from the scalar meson resonance K^*_0(1430) and from the scalar projection of the vector meson K^*(892) resonance. We analyze decay amplitudes of the Cabibbo suppressed decays D->K P, P =\pi,\eta,\eta' using the factorization approach. The form factors of the relevant matrix elements are described by assuming the dominance of nearby resonances. The annihilation contribution in these decays arises from the matrix element <P K| j_\mu |0>. All the required parameters are experimentally known except the scalar meson K^*_0(1430) decay constant. We fit the decay amplitudes and we find that final state interaction improves the agreement with the experimental data. Then we extract bounds on scalar form factor parameters and compare them with the experimental data obtained in the analyses of K->\pi e\nu_e and K->\pi\mu\nu_\mu. The same scalar form factor is present in the \tau-> K P \nu_\tau decay, with P =\pi,\eta,\eta'. Using the obtained bounds we investigate the significance of the scalar meson form factor in the \tau-> K P \nu_\tau, P = \pi, \eta, \eta' decay rates and spectra. We find that the K^*_0(1430) scalar meson dominates in the \tau-> K \eta'\nu_\tau decay spectrum.