D. Snowden scite author profile

Photochemically produced aerosols are common among the atmospheres of our solar system and beyond. Observations and models have shown that photochemical aerosols have direct consequences on atmospheric properties as well as important astrobiological ramifications, but the mechanisms involved in their formation remain unclear. Here we show that the formation of aerosols in Titan's upper atmosphere is directly related to ion processes, and we provide a complete interpretation of observed mass spectra by the Cassini instruments from small to large masses. Because all planetary atmospheres possess ionospheres, we anticipate that the mechanisms identified here will be efficient in other environments as well, modulated by the chemical complexity of each atmosphere.planetary sciences | heterogeneous chemistry | particles charging | plasma P hotochemical aerosols are observed in many atmospheres of our solar system (1-3), and their presence is also detected in exoplanet atmospheres (4). Apart from their direct influence on the atmospheric properties through their interaction with the radiation field, aerosols have further astrobiological implications; their presence in the early Earth's atmosphere could have protected the surface and any life evolving there from UV radiation (5), and laboratory studies of Titan aerosol analogs have identified an in vitro formation of amino acids during aerosol production (6). However, the general mechanisms involved in the production and growth of photochemical aerosols from atmospheric gases have remained elusive. Titan, as the most extreme example of an aerosol-dominated atmosphere, provides a unique opportunity to investigate these mechanisms.Cassini observations revealed the presence of aerosols in multiple regions of the atmosphere, from the troposphere (7), stratosphere (8), and mesosphere (9, 10) up to the thermosphere where the detection of large mass positive and particularly negative ions has been suggested to be the signature of aerosol formation (11)(12)(13)(14). During a recent flyby (T70), the Cassini spacecraft penetrated to deeper regions of Titan's thermosphere than usual, reaching altitudes close to 880 km that had not previously been sampled with in situ measurements. Measurements from the Langmuir probe (LP) during this unique flyby reveal a high abundance of negative ions at closest approach, comparable to the positive ion density, and a corresponding decrease in the electron density (15). This conclusion is supported by the analysis of multiple Cassini observations, which reveals that the observed electron density is smaller than the density anticipated from photochemical equilibrium, implying that the photochemical models are missing a significant electron loss mechanism (16, 17). Thus, current observations demonstrate a significant decrease of the electron density relative to the positive ion density in the lower ionosphere with a concurrent increase in the density of the negative ions.Aerosols, or dust particles in general, are known to interact with free electr...

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The thermal structure of Titan’s upper atmosphere, I: Temperature profiles from Cassini INMS observations

Snowden

Yelle

Cui

et al. 2013

Icarus

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The CH₄structure in Titan's upper atmosphere revisited

et al. 2012

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[1] In this study, we reanalyze the CH 4 structure in Titan's upper atmosphere combining the Cassini Ion Neutral Mass Spectrometer (INMS) data from 32 flybys and incorporating several updates in the data reduction algorithms. We argue that based on our current knowledge of eddy mixing and neutral temperature, strong CH 4 escape must occur on Titan. Ignoring ionospheric chemistry, the optimal CH 4 loss rate is $3 Â 10 27 s À1 or 80 kg s À1 in a globally averaged sense, consistent with the early result of Yelle et al. (2008). The considerable variability in CH 4 structure among different flybys implies that CH 4 escape on Titan is more likely a sporadic rather than a steady process, with the CH 4 profiles from about half of the flybys showing evidence for strong escape and most of the other flybys consistent with diffusive equilibrium. CH 4 inflow is also occasionally required to interpret the data. Our analysis further reveals that strong CH 4 escape preferentially occurs on the nightside of Titan, in conflict with the expectations of any solar-driven model. In addition, there is an apparent tendency of elevated CH 4 escape with enhanced electron precipitation from the ambient plasma, but this is likely to be a coincidence as the time response of the CH 4 structure may not be fast enough to leave an observable effect during a Titan encounter.

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D. Snowden

The mesosphere and lower thermosphere of Titan revealed by Cassini/UVIS stellar occultations

Aerosol growth in Titan’s ionosphere

The thermal structure of Titan’s upper atmosphere, I: Temperature profiles from Cassini INMS observations

The CH₄structure in Titan's upper atmosphere revisited

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D. Snowden

The mesosphere and lower thermosphere of Titan revealed by Cassini/UVIS stellar occultations

Aerosol growth in Titan’s ionosphere

The thermal structure of Titan’s upper atmosphere, I: Temperature profiles from Cassini INMS observations

The CH4structure in Titan's upper atmosphere revisited

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Product

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The CH₄structure in Titan's upper atmosphere revisited