Measurement and prediction of the speed-dependent throughput of a magnetic octupole velocity filter including nonadiabatic effects

A magnetic octupole filter set in a 90 degree sign curve produces {approx_equal}10{sup 8} cold Rb atoms/s by filtering low-velocity particles from a thermal source. We measure the speed distribution of Rb exiting the filter to be 3.5 K using a Rydberg-atom time-of-flight scheme in which Rb is excited via the process 5s {sup 2}S{sub 1/2}{yields}5p {sup 2}P{sub 3/2}{sup o}{yields}32d {sup 2}D. We develop a general theory of the transmission and speed distribution of particles emitted from such a source including nonadiabatic effects. A detailed Monte Carlo simulation using the theory accurately reproduces the experimental results. We show that for Cs, Li, and Rb atoms and S{sub 2} molecules, nonadiabatic effects do not dramatically effect the performance of the filter, and that the output flux temperatures for a wide variety of filter configurations are well fit to a simple functional form.