Portal de Periódicos da CAPES

An ion‐molecule mechanism for the formation of neutral sporadic Na layers

1998; American Geophysical Union; Volume: 103; Issue: D6 Linguagem: Inglês

10.1029/97jd03376

2156-2202

Rachel M. Cox, J. M. C. Plane,

Ionosphere and magnetosphere dynamics

This paper describes a laboratory study into the chemical pathways by which Na + is converted to Na in the upper atmosphere. The termolecular clustering reactions of Na + with N 2 , O 2 , and CO 2 were studied in a low‐temperature fast flow reactor coupled to a quadrupole mass spectrometer. This yielded k (Na + + N 2 + He, 93–255 K) = (1.20±0.13) × 10 −30 ( T / 200 K) −(2.20±0.09) , k (Na + + O 2 + He, 93–130 K) = (5.20±2.62) × 10 −31 ( T / 200 K) −(2.64±0.74) , k (Na + + CO 2 + He, 158–300 K) = (9.05±1.38) × 10 −30 ( T / 200 K) −(2.84±0.48) , where are cm 6 molecule −2 s −1 and the stated errors are a combination of the 2σ standard errors in the kinetic data and the systematic errors in the temperature, pressure, and flow rates. It was then shown that atomic O will ligand switch with Na. N 2 + but not with Na.CO 2 + , and that the former reaction proceeds essentially at the Langevin collision frequency. The neutralization of Na + in the upper atmosphere is therefore rather complex. The first step is formation of the Na.N 2 + ion from the recombination of Na + with N 2 . This cluster ion can then either switch with O 2 , which leads to a stable cluster ion that will undergo dissociative electron recombination to form Na; or switch with atomic O, which reforms Na + . The result of this is that the lifetime of Na + changes very rapidly from more than a day above 100 km to just a few minutes at 90 km. Furthermore, the rate of neutralization is largely independent of the electron concentration. A simple model describing the conversion of Na + to atomic Na in a descending sporadic E layer demonstrates that this ion‐molecule mechanism appears to fulfil many of the major criteria for producing sporadic sodium layers.