A time-resolved model of the mesospheric Na layer: constraints on the meteor input function

Plane, J. M. C.

doi:10.5194/acp-4-627-2004

Cited by 164 publications

(267 citation statements)

References 43 publications

Supporting

Mentioning

238

Contrasting

Order By: Relevance

“…In the mesosphere and lower thermosphere (MLT), Na + ions and sodium bicarbonate (NaHCO 3 ) are the major reservoir species above and below the atomic Na layer, respectively (Plane et al, 1999;Plane, 2004). Due to the long residence time (∼7 days) of ablated sodium in the region between 80 and 100 km (Plane, 2004), and the comparatively short lifetimes of the ratedetermining 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 . Consequently, atmospheric chemistry plays a key role in determining the atomic Na distribution.…”

Section: Global Latitudinal and Seasonal Variationsmentioning

confidence: 99%

See 1 more Smart Citation

Satellite measurements of the global mesospheric sodium layer

et al. 2007

Self Cite

View full text Add to dashboard Cite

Abstract. Optimal estimation theory is used to retrieve the absolute Na density profiles in the mesosphere/lower thermosphere from limb-scanning measurements of the Na radiance at 589 nm in the dayglow. Two years of observations (2003 and 2004), recorded by the OSIRIS spectrometer on the Odin satellite, have been analysed to yield the seasonal and latitudinal variation of the Na layer column abundance, peak height, and peak width. The layer shows little seasonal variation at low latitudes, but the winter/summer ratio increases from a factor of ∼3 at mid-latitudes to ∼10 in the polar regions. Comparison of the measurements made at about 06:00 and 18:00 LT shows little diurnal variation in the layer, apart from the equatorial region where, during the equinoxes, there is a two-fold increase in Na density below 94 km between morning and evening. This is most likely caused by the strong downward wind produced by the diurnal tide between ∼02:00 and 10:00 LT. The dramatic removal of Na below 85 km at latitudes above 50 • during summer is explained by the uptake of sodium species on the ice surfaces of polar mesospheric clouds, which were simultaneously observed by the Odin satellite.

show abstract

Section: Global Latitudinal and Seasonal Variationsmentioning

confidence: 99%

“…Consequently, atmospheric chemistry plays a key role in determining the atomic Na distribution. Na is converted to NaHCO 3 via the following sequence of reactions (Plane, 2004):…”

Section: Global Latitudinal and Seasonal Variationsmentioning

confidence: 99%

Satellite measurements of the global mesospheric sodium layer

et al. 2007

Self Cite

View full text Add to dashboard Cite

show abstract

“…Below 90 km, the main chemical reaction that produces sodium atoms is NaHCO 3 + hv → Na + HCO 3 . The reaction rate coefficients are listed in Table 1 of Plane [2004]. The potential correlations between SSLs and the temperature structure have also been studied previously [Hansen and von Zahn, 1990;Zhou et al, 1993;Gardner et al, 1995;Delgado et al, 2012].…”

Section: Temperature Mechanismmentioning

confidence: 99%

“…And a less pronounced link, or absence of a link, between Es and SSL is observed below 95 km [Hansen and Von Zahn, 1990]. Second, the complex SSL chemical process has been published [Cox and Plane, 1998;Collins et al, 2002;Plane, 2003Plane, , 2004 while SSLs and temperature have been observed simultaneously [Hansen and Von Zahn, 1990;Gardner et al, 1993Gardner et al, , 1995Batista et al, 2002]. Temperature-independent conjecture Zhou and Mathews, 1995] and modeling [Delgado et al, 2012] along with sporadic neutral metal atom layers have been studied and discussed.…”

Section: Introductionmentioning

confidence: 99%

Sodium lidar‐observed gravity wave breaking followed by an upward propagation of sporadic sodium layer over Hefei, China

Ban

Fang

et al. 2015

JGR Space Physics

View full text Add to dashboard Cite

The University of Science and Technology of China sodium temperature/wind lidar observed a strong zonal wind shear (~60 m/s/km) near 98 km between 1315 and 1330 UT on 29 July 2013 and a cooling near 96–100 km (above a warming near 90–95 km) between 1330 and 1430 UT. This suggests a possible gravity wave (GW) breaking event. Comparison of the lidar results with observations from a nearby meteor radar and with satellite results indicated that the GW likely broke down over a large horizontal area. In addition, the sodium number density suddenly increased 10–12 times (∼13, 000atm/cm3) near 95 km at 1400 UT, immediately following the GW breaking. This sporadic sodium layer (SSL), which is different from most previously observed SSL events (which propagate downward), tended to propagate upward and also appeared ~2 min earlier in the west channel than in the east channel. The horizontal propagation direction of the SSL was aligned with the horizontal wind direction, which was likely due to the propagation of a high‐density sodium layer from the northwest of the lidar site, and was possibly related to the earlier GW breaking event.

show abstract

“…It has recently attracted a renewed interest, because, besides the scientific questions related to the origin and the vertical distribution of the layer, the mesospheric sodium is of major importance in astronomy, where it is used to produce an artificial star on which to base guidance for adaptive optics with a lidar illumination. Although extensive data exist about the mesospheric sodium layer measured from particular sites, very little is known about the geographical distribution (Plane, 2004). GOMOS has demonstrated a new method of studying the sodium layer, and has provided the first global mesospheric sodium climatology made so far .…”

Section: Detection and Climatology Of The Natural Sodium Layermentioning

confidence: 99%

Global ozone monitoring by occultation of stars: an overview of GOMOS measurements on ENVISAT

et al. 2010

View full text Add to dashboard Cite

Abstract. GOMOS on ENVISAT (launched in February, 2002) is the first space instrument dedicated to the study of the atmosphere of the Earth by the technique of stellar occultations (Global Ozone Monitoring by Occultation of Stars). Its polar orbit makes good latitude coverage possible. Because it is self-calibrating, it is particularly well adapted to long time trend monitoring of stratospheric species. With 4 spectrometers, the wavelength coverage of 248 nm to 942 nm enables monitoring ozone, H 2 O, NO 2 , NO 3 , air density, aerosol extinction, and O 2 . Two additional fast photometers (with 1 kHz sampling rate) enable the correction of the effects of scintillations, as well as the study of the structure of air density irregularities resulting from gravity waves and turbulence. A high vertical resolution profile of the temperature may also be obtained from the time delay between the red and the blue photometer. Noctilucent clouds (Polar Mesospheric Clouds, PMC) are routinely observed in both polar summers and global observations of OClO and sodium are achieved.The instrument configuration, dictated by the scientific objectives' rationale and technical constraints, is described, together with the typical operations along one orbit, along with the statistics from over 6 years of operation. Typical atmospheric transmission spectra are presented and some retrieval difficulties are discussed, in particular for O 2 and H 2 O.Correspondence to: J. L. Bertaux (bertaux@latmos.ipsl.fr) An overview is presented of a number of scientific results already published or found in more detail as companion papers in the same ACP GOMOS special issue. This paper is particularly intended to provide an incentive for the exploitation of GOMOS data available to the whole scientific community in the ESA data archive, and to help GOMOS data users to better understand the instrument, its capabilities and the quality of its measurements, thus leading to an increase in the scientific return.

show abstract

A time-resolved model of the mesospheric Na layer: constraints on the meteor input function

Cited by 164 publications

References 43 publications

Satellite measurements of the global mesospheric sodium layer

Satellite measurements of the global mesospheric sodium layer

Sodium lidar‐observed gravity wave breaking followed by an upward propagation of sporadic sodium layer over Hefei, China

Global ozone monitoring by occultation of stars: an overview of GOMOS measurements on ENVISAT

Contact Info

Product

Resources

About