Universal non-monotonic structure in the saturation curves of MOT-loaded Na+ ions stored in an ion-neutral hybrid trap: Prediction and observation

Abstract

We predict that the steady-state ion number Ns for radio-frequency (rf) traps, loaded at a rate of λ particles per unit time, shows universal non-monotonic behavior as a function of loading rate λ. The shape of Ns(λ), characterized by four dynamical regions, is universal in the sense that it is predicted to manifest itself in all rf traps independently of the details of their construction. For λ 1 particles / rf cycle (Region I), as expected, Ns(λ) increases monotonically with λ. However, contrary to intuition, at intermediate λ 1 particles / rf cycle (Region II), Ns(λ) reaches a maximum, followed by a minimum of Ns(λ) (Region III). For λ 1 particles / rf cycle (Region IV), Ns(λ) again rises monotonically. In Region IV numerical simulations, analytical calculations, and experiments show Ns(λ) λ2/3. We confirm this prediction experimentally with MOT-loaded Na+ ions stored in a hybrid ion-neutral trap.