Physical properties of the organic aerosols and clouds on Titan

McKay, Christopher P.; Coustenis, A.; Samuelson, R. E.; Lemmon, M. T.; Lorenz, Ralph D.; Cabane, Michel; Rannou, P.; Drossart, P.

doi:10.1016/s0032-0633(00)00051-9

Cited by 157 publications

(130 citation statements)

References 125 publications

(250 reference statements)

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“…Previous experiments forming early Earth aerosols using a discharge source readily formed fractal aggregates with diameters Ͼ0.10 m (28), which would be expected to show different optical properties compared with the spherical monomers (41). These fractal aggregates are consistent with microphysical models for Titan (42). Thus, the UV shielding of a photochemically produced haze layer on early Earth would depend strongly on whether the particles observed eventually form fractal aggregates in the atmosphere.…”

Section: Implications For Early Earthsupporting

confidence: 58%

Organic haze on Titan and the early Earth

et al. 2006

Proc. Natl. Acad. Sci. U.S.A.

238

267

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Recent exploration by the Cassini͞Huygens mission has stimulated a great deal of interest in Saturn's moon, Titan. One of Titan's most captivating features is the thick organic haze layer surrounding the moon, believed to be formed from photochemistry high in the CH 4͞N2 atmosphere. It has been suggested that a similar haze layer may have formed on the early Earth. Here we report laboratory experiments that demonstrate the properties of haze likely to form through photochemistry on Titan and early Earth. We have used a deuterium lamp to initiate particle production in these simulated atmospheres from UV photolysis. Using a unique analysis technique, the aerosol mass spectrometer, we have studied the chemical composition, size, and shape of the particles produced as a function of initial trace gas composition. Our results show that the aerosols produced in the laboratory can serve as analogs for the observed haze in Titan's atmosphere. Experiments performed under possible conditions for early Earth suggest a significant optical depth of haze may have dominated the early Earth's atmosphere. Aerosol size measurements are presented, and implications for the haze layer properties are discussed. We estimate that aerosol production on the early Earth may have been on the order of 10 14 g⅐year ؊1 and thus could have served as a primary source of organic material to the surface.planetary atmospheres ͉ tholins ͉ atmospheric aerosol ͉ Archaen ͉ astrobiology

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Section: Implications For Early Earthsupporting

confidence: 58%

Organic haze on Titan and the early Earth

et al. 2006

Proc. Natl. Acad. Sci. U.S.A.

238

267

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“…It was noted that more methane could be seen at longer wavelengths, indicating that scattering in the atmosphere was important and suggesting that the atmosphere might be optically thick in the visible. We now know that the haze is optically thick at all wavelengths below 1 µm, but becomes increasingly transparent at longer wavelengths, in part because the aerosols are absorbing below 0.5 µm, but scattering above 0.7 µm (see, for example, the models of Griffith et al (1991), the observations of the surface by Lemmon et al (1993), and the recent review by McKay et al (2001)). …”

Section: Modeling the Methane Spectrummentioning

confidence: 99%

Methane Abundance on Titan, Measured by the Space Telescope Imaging Spectrograph

Lemmon

Smith

Lorenz

2002

Icarus

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Although methane is the dominant absorber in Titan's reflection spectrum, the amount of methane in the atmosphere has only been determined to an order of magnitude. We analyzed spectra from the Space Telescope Imaging Spectrograph, looking at both a bright surface region (700-km radius) and a dark surface region. The difference between the spectra of the two regions is attributed to light that has scattered off the surface, and therefore made a roundtrip through all of Titan's methane. Considering only absorption, the shape of the difference spectrum provides an upper limit on methane abundance of 3.5 km-am. Modeling the multiple scattering in the atmosphere further constrains the methane abundance to 2.63 ± 0.17 km-am. In the absence of supersaturation and with a simplified methane vertical profile, this corresponds to a surface methane-mole fraction near 3.8% and a relative humidity of 0.32. With supersaturation near the tropopause, the surface methane mole fraction could be as low as 3%. c 2002 Elsevier Science (USA)

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“…16 Therefore, hydrocarbon molecules play a crucial role in the radiation and temperature balance. 17 Third, Titan's haze makes an important contribution to the dynamics of the atmosphere. 18,19 This leads to latitudinal and seasonal patterns of hydrocarbons in the atmosphere of Titan.…”

Section: Introductionmentioning

confidence: 99%

Crossed Molecular Beams Study on the Formation of Vinylacetylene in Titan’s Atmosphere

Zhang

Kim²,

Kaiser³

et al. 2009

J. Phys. Chem. A

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The reaction of ground-state ethynyl radicals, C 2 H(X 2 Σ + ), with d 4 -ethylene, C 2 D 4 (X 1 A g ), was investigated at a collision energy of 20.6 ( 0.4 kJ mol -1 utilizing the crossed-beams technique. Combined with electronic structure calculations, our results elucidate that this reaction follows indirect reaction dynamics via a doublet radical complex. The reaction is initiated by a barrierless addition of the ethynyl radical to a carbon atom of the d 4 -ethylene molecule to form a C 4 HD 4 intermediate. The latter is long-lived compared with its rotational period and decomposes via a tight exit transition state to form the d 3 -vinylacetylene product (HCCC 2 D 3 ) plus a deuterium atom while conserving the ethynyl group; the center-of-mass angular distribution suggests that the deuterium atom leaves almost perpendicularly to the rotational plane of the fragmenting C 4 HD 4 complex. The overall reaction is found to be exoergic by 94 ( 20 kJ mol -1 ; this value agrees nicely with a computational data of 103 ( 5 kJ mol -1 . This study indicates that the analogous vinylacetylene molecule (HCCC 2 H 3 ) can be synthesized in a low-temperature environment such as Titan's atmosphere via the neutral-neutral reaction of ethynyl radicals with ubiquitous ethylene. The similarity between this reaction and that of the isoelectronic cyano radical, CN(X 2 Σ + ), with ethylene-yielding vinylcyanide (C 2 H 3 CN) is also discussed.

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Physical properties of the organic aerosols and clouds on Titan

Cited by 157 publications

References 125 publications

Organic haze on Titan and the early Earth

Organic haze on Titan and the early Earth

Methane Abundance on Titan, Measured by the Space Telescope Imaging Spectrograph

Crossed Molecular Beams Study on the Formation of Vinylacetylene in Titan’s Atmosphere

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