Modeling the seasonality of wind-driven hydrocarbon waves in Titan’s polar lake

Charlene E. Detelich; Una G. Schneck; Alexander G. Hayes; Milan Curcic; Rose Elizabeth Palermo; Andrew D. Ashton; J. Taylor Perron; Juan M. Lora; Jordan Steckloff

doi:10.1029/2026JE009693

Modeling the seasonality of wind-driven hydrocarbon waves in Titan’s polar lake

JGR Planets

By: Charlene E. Detelich, Una G. Schneck, Alexander G. Hayes, Milan Curcic, Rose Elizabeth Palermo, Andrew D. Ashton, J. Taylor Perron, Juan M. Lora, and Jordan Steckloff

https://doi.org/10.1029/2026JE009693

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Abstract

Titan, the only body in the solar system aside from Earth with standing liquids on its surface, has polar hydrocarbon lakes and seas. As Titan’s atmosphere generates light winds, there should be waves on the surface of these lakes and seas, yet, direct wave observations are scant. We introduce and use PlanetWaves, an open source 4D spectral wave model, to study Titan’s waves and create seasonal maps of wave shape and propagation on Ontario Lacus and Ligeia Mare. Titan’s modeled waves grow up to 30 times larger than terrestrial waves for the same wind speed, are seasonally present and are largest in the spring and summer when winds are strongest. Average daily winds almost never exceed the wave generation threshold of 0.5–0.7 m/s. Average storm winds (∼1.5 m/s) generate waves 15–48 cm in height with a period ranging 6–10.5 s while maximum storm winds (∼4 m/s) generate waves 2.7–3.2 m in height with a period up to 32 s. Titan’s waves become fetch-independent at ∼40 km for average storm winds occurring ∼1% of a Titan year and ∼100 kilometers for maximum storm winds occurring 2-3 times per Titan decade. On Ontario Lacus, storm winds blow nearly parallel to the eastern shore, potentially driving wave modification of the smooth eastern shoreline. On Ligeia Mare, waves rarely propagate toward a hypothesized wave modified shoreline suggesting that another process, such as tectonics, may contribute to a straight shoreline morphology.

Suggested Citation

Detelich, C.E., Schneck, U.G., Hayes, A.G., Curcic, M., Palermo, R.E., Ashton, A.D., Perron, J.T., Lora, J.M., and Steckloff, J., 2026, Modeling the seasonality of wind-driven hydrocarbon waves in Titan’s polar lake: JGR Planets, v. 131, no. 6, e2026JE009693, 26 p., https://doi.org/10.1029/2026JE009693.

Additional publication details
Publication type	Article
Publication Subtype	Journal Article
Title	Modeling the seasonality of wind-driven hydrocarbon waves in Titan’s polar lake
Series title	JGR Planets
DOI	10.1029/2026JE009693
Volume	131
Issue	6
Publication Date	May 21, 2026
Year Published	2026
Language	English
Publisher	American Geophysical Union
Contributing office(s)	St. Petersburg Coastal and Marine Science Center
Description	e2026JE009693, 26 p.
Other Geospatial	Titan