Abstract

We demonstrate that periodic, large-amplitude, low-frequency disturbances on a planar jet can increase spreading and mixing of a planar jet with the surrounding fluid. This is achieved by enhancing the natural instabilities of the jet, resulting in the formation of large vortical structures in the mixing layers. The jet had a Reynolds number of about 7.2×10 3 , an aspect ratio of 47, and Strouhal numbers, based on the nozzle width and the disturbance frequency, up to 0.324. A relatively new technique, full-held infrared imaging, was used to determine jet behavior and mixing. This technique provides a significant advantage over conventional temperature measurement techniques. Over 68,000 data points can be monitored as often as 30 times each second