Mesospheric Na layer at extreme high latitudes in summer

Plane, J. M. C.; Cox, Rachel M.; Qian, Jun; Pfenninger, William; Papen, George C.; Gardner, Chester S.; Espy, P. J.

doi:10.1029/96jd03709

Cited by 46 publications

(52 citation statements)

References 25 publications

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“…Because of the long residence time (∼7 days) of ablated sodium in the region between 80 and 100 km, and the comparatively short lifetimes of the rate-determining chemical reactions that convert sodium between atomic Na and these reservoirs, the chemistry reaches a photochemical steady-state on the timescale of vertical transport by eddy or molecular diffusion. The chemical reactions responsible for the conversion of Na to NaHCO 3 occur rapidly and have small temperature dependencies (Plane 2004(Plane , 1998. NaHCO 3 is converted back to Na by the reaction with H. This reaction has a large activation energy, that is at higher temperatures it becomes much faster, and the steady-state balance shifts from NaHCO 3 to Na (Cox et al 2001).…”

Section: Mesospheric Sodium Layer Chemistrymentioning

confidence: 99%

Statistics of the sodium layer parameters at low geographic latitude and its impact on adaptive-optics sodium laser guide star characteristics

Moussaoui

Clemesha

Holzlöhner³

et al. 2010

A&A

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Aims. To aid the design of laser guide star (LGS) assisted adaptive optics (AO) systems, we present an analysis of the statistics of the mesospheric sodium layer based on long-term observations (35 years). Methods. We analyze measurements of the Na-layer characteristics covering a long period , acquired at latitude 23 • south, in São José dos Compos, São Paulo, Brazil. We note that Paranal (Chile) is located at latitude 24 • south, approximately the same latitude as São Paulo.Results. This study allowed us to assess the availability of LGS-assisted AO systems depending on the sodium layer properties. We also present an analysis of the LGSs spot elongation over the year, as well as the nocturnal and the seasonal variation in the mesospheric sodium layer parameters. Conclusions. The average values of the sodium layer parameters are 92.09 km for the centroid height, 11.37 km for the layer thickness, and 5 × 10 13 m −2 for the column abundance. Assuming a laser of sufficient power to produce an adequate photon return flux for an AO system with a column abundance of 4 × 10 13 m −2 , a telescope could observe at low geographic latitudes with the sodium LGS more than 250 days per year. Increasing this power by 20%, we could observe throughout the entire year.

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Section: Mesospheric Sodium Layer Chemistrymentioning

confidence: 99%

Statistics of the sodium layer parameters at low geographic latitude and its impact on adaptive-optics sodium laser guide star characteristics

Moussaoui

Clemesha

Holzlöhner³

et al. 2010

A&A

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“…observation; furthermore, the steep underside of the Na layer indicates that a fairly rapid recycling of Na must occur [Plane et al, 1998]. Hence a measurement of k4 provides a rather stringent test of the current understanding of mesospheric sodium chemistry.…”

Section: Nahco3 + H --> Na + H2co 3 (Or H20 + Co2) (4)mentioning

confidence: 99%

“…Since only Na atoms and Na + ions can bc observed (by lidar and rocket-borne mass spcctromctry, respectively), the mcsosphcric chemistry of sodium has had to bc unraveled through laboratory kinetic studies of elementary reactions, coupled with modeling. Significant progress has been made over the past decade, with models that arc now able to reproduce the characteristic features of the Na layer remarkably well, over a range of latitudes and seasons [Helmer and Plane, 1993;McNeil et al, 1995;Plane et al, 1998Plane et al, , 1999.…”

Section: Introductionmentioning

confidence: 99%

A study of the reaction between NaHCO₃ and H: Apparent closure on the chemistry of mesospheric Na

Cox¹,

Self²,

Plane³

2001

J. Geophys. Res.

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“…He proposed that the seasonal differences between Na and K might be explained by the kinetics of key potassium reactions having smaller temperature dependences than their sodium analogues. However, the sodium model that he used was quite Plane et al, 1998Plane et al, , 1999.…”

Section: Paper Number 1999ja900117mentioning

confidence: 99%

The terrestrial potassium layer (75–110 km) between 71°S and 54°N: Observations and modeling

Eska¹,

Zahn²,

Plane³

1999

J. Geophys. Res.

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Abstract. Observations of the nighttime atmospheric potassium layer were performed on the German research vessel Polarstem from March to June 1996. K density profiles were obtained between 71øS and 45øN. The nightly mean peak densities ranged from 140 cm -3 in the equatorial region to 10 cm -3 in the Antarctic, and the column abundances decreased from 1.2 x 108 to 1.3 x 107 cm -2 going from low to high latitudes. High peak densities and column abundances were also commonly observed together with sporadic K layers. The global mean peak height of the normal (background) K layer was found to be 88.3 km. After the Polarstern campaign, observations were continued at Kfihlungsborn (54øN). The summer and winter K layers, observed during July 1996 and January 1997, were quite different in shape but had similar peak densities and column abundances. A one-dimensional model of the K layer was developed which includes meteoric deposition, vertical transport through eddy diffusion, and a full chemical scheme. This model was able to reproduce very satisfactorily the seasonal behavior of the K layer at 54øN if the wintertime deposition flux of the metal was reduced by 30% compared to the summer. The midlatitude ratio of K to Na was about 1%, much less than either the chondritic or cosmic ratios of the two metals (•8 or 6%, respectively). The most likely reason is that potassium vaporizes less efficiently from meteoroids than sodium, in agreement with a thermodynamic model of a nonideal chondritic magma and observations in the exosphere of Mercury. Finally, the model was generally very successful in reproducing the latitudinal variations in the K layer. IntroductionThe deposition of extraterrestrial material in the Earth's upper atmosphere gives rise to layers of free neutral metal atoms in the altitude range from 80 to 110 km [Plane, 1991]. Investigations of the K layer were initiated by Lytle and Hunten [1959], who were able to estimate the ratio of potassium to sodium. Some years later, Sullivan and Hunten [1962, 1964] determined the peak density and column abundance from weak twilight emission data by using a birefringent filter photometer. These measurements were continued by Gault and Rundle [1969] The first model of mesospheric potassium was developed by Swider [1987] from an existing model of sodium chemistry. He proposed that the seasonal differences between Na and K might be explained by the kinetics of key potassium reactions having smaller temperature dependences than their sodium analogues. However, the sodium model that he used was quite 17,173

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Mesospheric Na layer at extreme high latitudes in summer

Cited by 46 publications

References 25 publications

Statistics of the sodium layer parameters at low geographic latitude and its impact on adaptive-optics sodium laser guide star characteristics

Statistics of the sodium layer parameters at low geographic latitude and its impact on adaptive-optics sodium laser guide star characteristics

A study of the reaction between NaHCO₃ and H: Apparent closure on the chemistry of mesospheric Na

The terrestrial potassium layer (75–110 km) between 71°S and 54°N: Observations and modeling

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Mesospheric Na layer at extreme high latitudes in summer

Cited by 46 publications

References 25 publications

Statistics of the sodium layer parameters at low geographic latitude and its impact on adaptive-optics sodium laser guide star characteristics

Statistics of the sodium layer parameters at low geographic latitude and its impact on adaptive-optics sodium laser guide star characteristics

A study of the reaction between NaHCO3 and H: Apparent closure on the chemistry of mesospheric Na

The terrestrial potassium layer (75–110 km) between 71°S and 54°N: Observations and modeling

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A study of the reaction between NaHCO₃ and H: Apparent closure on the chemistry of mesospheric Na