Unexpected pattern of transitions to radial excitations by heavy quark current
Résumé
Motivated by the claimed possibility of a large contribution of the first radial excitation of the D(*) to the B semileptonic decay into charmed mesons, also invoked to solve the “1/2 vs 3/2 semileptonic puzzle,” we discuss the transitions to heavy-light radial excitations by a heavy b→c quark current. We first consider a HQET sum rule, which provides a bound on the slopes of Isgur-Wise functions, which we then calculate in the Bakamjian-Thomas framework, which both guaranties covariance in the heavy quark limit and satisfies a set of HQET sum rules. We observe a remarkable property that for a large variety of wave functions, the transition to the first radial excitation is very small, while the transition matrix element to the second radial excitation is large and dominant in saturating the HQET sum rule. This is opposite to what is found in nonrelativistic models, where the transition to the first radial excitation dominates the sum rule. The relative magnitude of the transition to the second excitation appears to be weakly dependent on the dynamical scale (radius of the bound states), and the same holds true for the slope of the elastic transition. These features could be tested in the heavy-mass limit of lattice QCD. This pattern is shown to be related to the general structure of the Bakamjian-Thomas model; it is independent of the spin structure of the approach and derives mainly from the Lorentz transformation of the spatial wave function, a feature often disregarded in quark models.
Mots clés
Isgur-Wise function: slope
transformation: Lorentz
model: nonrelativistic
quark: current
D*(2010): excited state
sum rule
Heavy Quark Effective Theory
wave function
heavy quark
quantum chromodynamics
lattice field theory
B: semileptonic decay
charmed meson: final state
bound state
quark model
covariance
spin