A theoretical study of the rotational distribution of no resulting from dissociation of HNO

Flash photolysis of CH3CHO and H2CO in the presence of NO has been investigated by the intracavity laser spectroscopy technique. The decay of HNO formed by the reaction HCO + NO \* HNO + CO was studied a t NO pressures of 6.&380 torr. At low NO pressure HNO was found to decay by the reaction HNO + H

The results or an ab mitlo study of the vlbrotuc and rotational slructure III lhc \*II stale of HNO+ are presented It is shoun that the absorption spectrum at 7200 A obscwcd by Hcabcrg could be caused by the transition from the ground IO the rust euxcd elecwomc state of HNO'

The high-temperature reaction of NO with H 2 has been studied behind reflected shock waves in the temperature range of 1760-2160 K at total pressures of 1.4 to 2.0 bar by monitoring the time-dependent H-atom concentrations in the postshock reaction zone using atomic resonance absorption spectroscopy

The chemiiumincscence in the rractions of H + NO and D + NO wcrc observed using 111t crossed diverging-brdm method. In either CJSC of HNO or DNO tic electronically elcitcd state (A 'A") is prefcrcntlaliy populated III the (000) vibrJt!onal state. As for the rotational distribution of the (000) vibr