Stratospheric dust and its relationship to the meteoric influx

Rosen, James M.

doi:10.1007/bf00187579

Cited by 49 publications

(22 citation statements)

References 82 publications

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“…According to Ferguson [1978], the positive ion mass spectra observed by Arnold et al [1977] between 35 and 45 km exhibit a mass sequence that may correspond to NaOHH+ ß (H20)n clusters. Utilizing this data, and employing ion chemistry rate coefficients measured for H2SO4 reactions by Viggiano et al [1980], •lrnold and Fabian [1980] deduced H2SO4 Direct observations of stratospheric aerosols also indicate a meteoric component [Rosen, 1969;Cadle. Unfortunately, Liu and Reid did not take into account sodium vapor removal on particles, and may have greatly overestimated the NaOH abundance (see below).…”

Section: Introductionmentioning

confidence: 99%

Effects of meteoric debris on stratospheric aerosols and gases

Turco¹,

Toon²,

Hamill³

et al. 1981

J. Geophys. Res.

102

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We consider the interactions of meteoric dust particles and metal vapors with stratospheric aerosols and gases. We utilize the detailed calculations of meteor ablation and recondensation rates made by Hunten et al. (1980) to obtain a fairly precise characterization of meteoric dust height and size distributions. We quantify the contribution of meteor residues to aerosol composition, the role of meteoric dust as condensation nuclei, and the effects of meteor debris on aerosol size distributions. We give estimates of particle surface areas, and discuss the potential importance of heterogeneous chemistry for stratospheric trace gases. We also investigate the interaction between H2SO4 vapor, which is associated with stratospheric aerosols, and meteor metal vapors, which are responsible for stratospheric metal ion composition. Our model predictions compare favorably with observational data on the elemental composition of aerosols, stratospheric particle size distributions, condensation nuclei abundances and sulfate mass mixing ratios. We conclude that meteoric particles may dominate the natural stratospheric aerosols at small (<0.01μm radius) and large (>1.0 μm) sizes under normal conditions. We show that metallic meteoric elements may act to neutralize sulfuric acid vapor above 20 km, significantly reducing ambient H2SO4 abundances. We also demonstrate that model calculations which neglect particle interactions can seriously overestimate stratospheric metal vapor concentrations.

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Section: Introductionmentioning

confidence: 99%

Effects of meteoric debris on stratospheric aerosols and gases

Turco¹,

Toon²,

Hamill³

et al. 1981

J. Geophys. Res.

102

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“…Giant particles may reach sufficiently high temperature to melt as they enter and pass through the Earth's atmosphere. These give rise to the spherules collected by balloons in the upper atmosphere and also in some ground level samplings (see Rosen, 1969;Zacharav, 1962;and Kuiz, 1962). Particles that fall within the size category representing aerosols will have a relatively long residence time within the upper atmosphere and, these are undoubtedly responsible for some of the sporatic and transient aerosol layers reported by different observers.…”

Section: B Extraterrestrial Sourcesmentioning

confidence: 99%

“…Particles that fall within the size category representing aerosols will have a relatively long residence time within the upper atmosphere and, these are undoubtedly responsible for some of the sporatic and transient aerosol layers reported by different observers. Rosen (1969) estimates that only a few percent of the quasi-steady state Junge layer at 20 km is composed of particles which can be classified as spherules. Gadsden (1968) has shown that ablation occurs as meteors enter the Earth's atmosphere, and that this may give rise to the sodium and other metal ion layer at ,-~93 km.…”

Section: B Extraterrestrial Sourcesmentioning

confidence: 99%

“…It has been found that the relative particle concentrations vary with time, but not in a regular seasonal fashion (Reiter, 1971). Although the data are sparse and their accuracy uncertain, they do suggest that the particle sizes are made up of 3 distinct distributions: one representing particles less than 0.1 #m, another for sizes between 0.1 and 5/~m, and a third for particle sizes above 5/~m (Rosen, 1969). It has been implied that particles ~<0.I/~m in size may be of terrestrial origin, while particles with diameters greater than 5/~m may represent meteoritic material.…”

Section: Chemical Considerations Of Upper Atmospheric Aerosol Layersmentioning

confidence: 99%

“…Recent reviews by Reiter (1971), Rosen (1969), and Cadle (1966), have given adequate, though sometimes conflicting, historical surveys of the early work and for this reason a detailed review will not be given here. In addition, * This research was performed under the auspices ofthe U.S. Atomic Energy Commission and partially financed by the Department of Transportation and the National Science Foundation under interagency agreements.…”

Section: Introductionmentioning

confidence: 99%

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Nucleation processes and aerosol chemistry

Castleman

1974

Space Sci Rev

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As the result of many observable optical phenomena, the occasional existence of upper atmospheric aerosols has been known since the beginning of the Century. Nevertheless, it is only during the last two decades that their persistent nature and extent of global distribution have become recognized. This review is addressed to the chemistry of upper atmospheric aerosols with particular attention to the chemical reactions and nucleation mechanisms responsible for their formation.Considering the stratosphere, it is now generally agreed that sulfate, mainly in the form of sulfuric acid, represents the single most abundant constituent of stratospheric aerosols. There is now strong evidence that these aerosols are formed in situ from sulfur bearing gases oxidized by free radicals. The various nucleation processes of atmospheric importance are reviewed, and it is shown that heteromolecular nucleation processes are almost certainly responsible for new particle formation in the stratosphere.The nature, and even existence, of aerosol layers above the stratosphere is less certain. The influx of extraterrestrial materials into the Earth atmosphere is estimated to be in the order of 50 to 500 tons per day. Considerations are given to the possible mechanisms which convert these materials to aerosol size particles. Although these particles provide one possible explanation for the appeareance of noctilucent clouds, nucleation about ions, most probably HaO + hydrates, is a strong contender as a more plausible formation mechanism. Considerable attention is given to this important atmospheric process, where it is shown that chemical forces contribute to the stability of the prenucleation clusters and the overall height of the energy barrier to nucleation. Finally, the role of aerosols in the sodium and other cycles of trace upper atmospheric constituents, is discussed.

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The Atmospheric Channel

Hemmati¹

2006

Deep Space Optical Communications

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Stratospheric dust and its relationship to the meteoric influx

Cited by 49 publications

References 82 publications

Effects of meteoric debris on stratospheric aerosols and gases

Effects of meteoric debris on stratospheric aerosols and gases

Nucleation processes and aerosol chemistry

The Atmospheric Channel

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