Intermittent saltation drives Mars-like sand transport on Titan

Comola, Francesco; Kok, Jasper F.; Lora, Juan M.; Cohanim, Kaylie; Yu, Xinting; He, Chao; McGuiggan, Patricia; Hörst, Sarah M.; Turney, F. A.

doi:10.21203/rs.3.rs-374505/v1

Cited by 2 publications

(1 citation statement)

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“…Thus, the tholins studied here are stickier than common polymers and other materials that have been used in past studies to simulate Titan sediments (Burr et al 2015;Méndez Harper et al 2017). If the surface sediments on Titan resemble the tholins studied here, then they are likely relatively sticky, which would have an impact on their transport on the surface of Titan (Comola et al 2021).…”

Section: Surface Energy Of Tholinsmentioning

confidence: 92%

A Cross-Laboratory Comparison Study of Titan Haze Analogs: Surface Energy

Li¹,

Yu²,

Sciamma-O’Brien³

et al. 2021

Preprint

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In Titan's nitrogen-methane atmosphere, photochemistry leads to the production of complex organic particles, forming Titan's thick haze layers. Laboratory-produced aerosol analogs, or "tholins", are produced in a number of laboratories; however, most previous studies have investigated analogs produced by only one laboratory rather than a systematic, comparative analysis. In this study, we performed a comparative study of an important material property, the surface energy, of seven tholin samples produced in three independent laboratories under a broad range of experimental conditions, and explored their commonalities and differences. All seven tholin samples are found to have high surface energies, and are therefore highly cohesive. Thus, if the surface sediments on Titan are similar to tholins, future missions such as Dragonfly will likely encounter sticky sediments. We also identified a commonality between all the tholin samples: a high dispersive (non-polar) surface energy component of at least 30 mJ/m 2 . This common property could be shared by the actual haze particles on Titan as well. Given that the most abundant species interacting with the haze on Titan (methane, ethane, and nitrogen) are non-polar in nature, the dispersive surface energy component of the haze particles could be a determinant factor in condensate-haze and haze-lake liquids interactions on Titan. With this common trait of tholin samples, we confirmed the findings of a previous study by that haze particles are likely good cloud condensation nuclei (CCN) for methane and ethane clouds and would likely be completely wetted by the hydrocarbon lakes on Titan.

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Section: Surface Energy Of Tholinsmentioning

confidence: 92%