Feasibility studues of a visible chemical laser from the detonation products of lead azide

Recent advances in the feasibility studies of a visible chemical laser from the detonation products of lead azide (LA) are reported. The spatial and temporal behavior of the detonation products, expanding into vacuum, is obtained via high-speed framing photography, transmission of a HeNe laser beam and chemiluminescence from excited Pb atoms. The photography reveals that following the initiation of LA the products form an expanding, bell-shaped cloud. The HeNe beam is attenuated when the cloud of products traverses its route. The intensity and the temporal behavior of the chemiluminescence depend on the distance to a barrier placed above the LA sample. The cloud contains gaseous products and solid particles which propagate perpendicular to the LA surface. By shining a pulsed beam of a Nd: YAG laser through the opaque cloud of products a hole is burned and a transparent medium is obtained. The characteristics of the hole and the expanding cloud are monitored by the HeNe beam and by the framing photography. The hole-burning is a result of eliminating solid particles from the cjoud. When the detonation products are expanded through a supersonic nozzle enhanced emission in the Pb (*P, °-'D₂) transition at 722.9 nm is observed. It is suggested that the enhanced emission is due to preferential excitation of Pb (³P₁ ⁰) via energy transfer from electronically excited N₂ combined with the effect of self-trapping of the emission from³P₁ ⁰ to the³P_{0, 1, 2} states. The expansion through the nozzle also causes a delay in the appearance of the attenuation. Our results show that enhanced emission in a transparent medium can be obtained following the detonation of LA by different means. The prospects to achieving visible lasing in this system are discussed.