Titan, the largest moon of Saturn, stands out as the only celestial body in our solar system—besides Earth—that showcases active rivers, lakes, and seas. What’s intriguing about Titan is that its river systems are believed to be flowing with liquid methane and ethane, feeding into lakes and seas that rival the size of Earth’s Great Lakes.
The confirmation of these vast seas and smaller lakes on Titan came in 2007 through detailed images captured by NASA’s Cassini spacecraft. This pivotal discovery propelled scientists into a quest for understanding the moon’s enigmatic liquid landscape.
Now, a dedicated team of geologists from MIT has delved into Titan’s shorelines, utilizing simulations to demonstrate that the large seas are likely shaped by wave activity. Previously, evidence of such waves had only been suggested indirectly through remote imaging of Titan’s terrain.
Instead of simply searching for direct visual signs of waves, the MIT team pioneered a different investigative approach. They initially modeled shoreline erosion processes observed on Earth and adapted these models to Titan’s seas to predict the type of erosion that could explain the shorelines captured in Cassini’s imagery. Their findings pointed strongly toward waves as the primary factor of erosion.
“Our results indicate that if coastal erosion is present on Titan, waves are the most probable cause,” states Taylor Perron, the Cecil and Ida Green Professor of Earth, Atmospheric and Planetary Sciences at MIT. “Standing at the shores of any of Titan’s seas, one could potentially witness waves of liquid methane and ethane lapping against the coastline, particularly during storm events, eroding the shore materials.”
Perron, alongside colleagues—including first author Rose Palermo, a former MIT-WHOI Joint Program graduate student now working as a research geologist at the U.S. Geological Survey—shared their findings in a recent publication in Science Advances. Their co-authors are MIT Research Scientist Jason Soderblom, former MIT postdoc Sam Birch (now an assistant professor at Brown University), Andrew Ashton from the Woods Hole Oceanographic Institution, and Alexander Hayes from Cornell University.
The Waves of Titan: A New Perspective
The question of wave activity on Titan has sparked some debate since Cassini first identified the presence of liquid on its surface.
“Some researchers did not find evidence for waves and argued that these seas appeared mirror-smooth,” explains Palermo. “Meanwhile, others noted some surface roughness but were uncertain if it was due to wave action.”
Understanding whether Titan’s seas experience wave activity could provide insights into the moon’s atmospheric conditions, including wind strength capable of generating such waves. Moreover, data on wave patterns could assist scientists in anticipating how Titan’s seas might change over time.
Rather than focus directly on identifying wave-like features, Perron and his team analyzed shoreline shapes to deduce potential erosion causes.
According to the current understanding, Titan’s seas likely formed when rising liquid levels inundated a landscape marked by river valleys. The researchers examined three possible scenarios for subsequent erosion: no erosion, wave-driven erosion, and “uniform erosion,” which may occur through either dissolution (where liquid gradually breaks down coastal materials) or the coast losing material due to its weight.
The research team simulated shoreline evolution for each scenario. For wave-driven erosion, they integrated a variable known as “fetch,” indicating the distance across which the wind blows over water to generate waves.
“Wave erosion hinges on both the height and angle of the waves,” Palermo elaborates. “The concept of fetch helps predict wave height, as greater fetch allows the wind to pick up more speed and create larger waves.”
In their study, they examined a simulated sea surrounded by flooded river valleys. By calculating the fetch distances along various points of the shoreline, they estimated potential wave heights and monitored how wave action could erode the initial shoreline shapes over time. This was juxtaposed against uniform erosion effects. Such comparative modeling was applied to a variety of starting shoreline shapes.
Results indicated significant differences in final shoreline forms based on the erosion mechanisms. Notably, while uniform erosion produced wider, more uniformly shaped shorelines, wave erosion refined the contours of shorelines facing long fetch distances, resulting in narrower and more rugged shapes in adjacent river valleys.
“Starting with the same shorelines, we found that distinct final shapes emerged depending on whether erosion was wave-driven or uniform,” Perron notes, emphasizing the notable contrasts between the two approaches.
To validate their simulations, the researchers compared their findings with actual lakes on Earth and noted similar distinctions between lakes shaped by waves versus those affected mainly by uniform erosion mechanisms.
Characterizing Titan’s Shoreline
The team revealed characteristic shoreline shapes informed by their respective erosion processes, prompting them to investigate where Titan’s shorelines might fit within these classifications.
They specifically focused on four of Titan’s largest, most thoroughly mapped seas: Kraken Mare (comparable to the Caspian Sea), Ligeia Mare (larger than Lake Superior), Punga Mare (longer than Lake Victoria), and Ontario Lacus (approximately 20% the size of its Earth counterpart).
Employing radar images from Cassini, the researchers mapped these sea shorelines and analyzed which erosion mechanism most convincingly explained their shapes. Their findings indicated that all four seas align closely with the wave-driven erosion model—supporting the hypothesis that waves have significantly shaped Titan’s shorelines.
“Our research suggests that if these coastlines have indeed eroded, their configurations strongly favor wave-induced erosion over uniform erosion or complete absence of erosion,” Perron concludes.
Juan Felipe Paniagua-Arroyave, associate professor at EAFIT University in Colombia, remarked that the team’s discoveries are paving new avenues for understanding extraterrestrial coastlines.
“Waves are a common phenomenon on Earth’s oceans. If Titan possesses similar waves, they would likely dominate the surface of its lakes,” Paniagua-Arroyave notes, expressing enthusiasm for studying how Titan’s winds generate waves of exotic liquid hydrocarbons rather than water. The research team plans to explore the wind conditions necessary for producing enough wave activity to erode Titan’s coasts continually, while also deciphering wind patterns from the shorelines’ shapes.
“Titan provides a unique example of an untouched system,” Palermo reflects. “It might offer insights into fundamental coastal erosion processes in the absence of human influence, potentially educating us on coastal management strategies for our own planet in the future.”
This research was made possible in part by funding from NASA, the National Science Foundation, the U.S. Geological Survey, and the Heising-Simons Foundation.
Photo credit & article inspired by: Massachusetts Institute of Technology