State control of phonon collision in a spherical Bose-Einstein condensate

The control of collective excitations and collision between them provides a forefront for understanding non-equlibrium many-body dynamics. Ultracold atomic gases with a tunability are excellent for conducting such a new quantum control. Previous experiments were performed mostly in anisotropic traps due to technical challenges. Consequently, the energy spectra of excitation modes are densely distributed with less or no well-defined symmetry, which makes it difficult to accurately manipulate coherent excitations. Here we produce a spherical Rb Bose-Einstein condensate (BEC) in an optical dipole trap and observe the phonon parametric down-conversion (PPDC). The conversion process shows that a high-energy mode is coupled to a low-energy mode with a half eigen-frequency. The spherical symmetry, which is crucial for observing the PPDC, is experimentally verified by measuring the collective modes and expansion behaviors of the condensate.