Collisional coupling of N2(B3Πg) and N2(W3Δu) states studied by laser-induced fluorescence

The quenching kinetics of N,(B3ng, u),have been determined in a low-prcwre flow system in the abscncc of N atoms. Individual vibration?1 levels of the B staic were populated by laser pumping (firsr-positive bands) of N?(A31G) molecules. The latter were created upstream by energy transfer from Ar met

The collision-induced intramolecular energy transfer N2 (A '2: ) + M+N2 (B 'll,) + M was studied under molecular beam conditions using Xe and Nz as the collision partners. Specifically, the near-resonant transfer between the levels A, VI'= 1 O-B, u'= 2 was investigated by means of the product emissi

N2B3ng, Y = O-2 and N\*a"v;, Y = 0 were produced by pulsed rodiolysis af nitrogen (100-2000 torr) and fo!lowed by fast kinetic absorption spectroscopy in the second and fifth positive system. T!le rate constants for the denctivation of the species by nitrogen were found to be ~N~A,~ = 1.6i + 0.8; 2.

The extension of high-resolution observation of the electronic emission spectrum of 14 N 2 toward the infrared domain is presented. To date, rotational analysis of the widely investigated spectrum of the N 2 molecule was done in a spectral domain ranging from 2500 cm Ϫ1 to the UV. We have recorded f

The laser-induced fluorescence (LIF) spectrum of the B 3 ⌸ 0 ϩ u -X 1 ⌺ g ϩ system of Br 2 was recorded by Fourier transform spectroscopy (FTS). The LIF spectra were obtained by using continuous-wave dye laser excitation in the spectral region 16 800 -18 000 cm Ϫ1 . About 1800 rotationally resolved

The spectroscopy of the Br 2 B 3 P(0 / u ) -X 1 S / g system has been revisited using both high-resolution Fourier transform spectroscopy and laser-induced fluorescence techniques. Improved rotational constants are reported based on an analysis of 97 vibrational bands observed in absorption at 0.02