Testing the scalar sector of the standard-model extension with neutron gravity experiments

In the present study we analyse, within the scalar sector of the standard-model extension framework, the influence of a spontaneous Lorentz symmetry breaking on gravitational quantum states of ultracold neutrons. The model is framed according to the laboratory conditions of the recent high-sensitivity GRANIT and qBounce experiments. The high-precision data achieved in such experiments allow us to set bounds on the symmetry breaking parameters of the model. The effective Hamiltonian governing the neutron's motion along the axis of free fall is derived explicitly. It describes a particle in a gravitational field with an effective gravitational constant controlled non-trivially by the Lorentz-violating parameters. In particular, using the exact wave functions and the energy spectrum, we evaluate both the heights associated with the quantum states and the transition frequencies between neighborhoring quantum states. By comparing our theoretical results with those reported in the GRANIT and the qBounce experiments, upper bounds on the Lorentz-violating parameters are determined. We also consider for the first time the gravity-induced interference pattern in a COW-type experiment to test Lorentz-invariance. In this case, an upper bound for the parameters is established as well.

Automated summary

In this study, we investigate the influence of spontaneous Lorentz symmetry breaking on gravitational quantum states of ultracold neutrons within the scalar sector of the standard-model extension framework. By analyzing high-precision data from GRANIT and qBounce experiments, we are able to set bounds on the symmetry breaking parameters. The derived effective Hamiltonian describes the neutron's motion in a gravitational field with an effective gravitational constant controlled by the Lorentz-violating parameters. Additionally, we consider the gravity-induced interference pattern in a COW-type experiment for the first time and establish an upper bound for the parameters.