Saturn’s ring rain is a downpour, not a drizzle

A surprising amount of complex organic molecules fall from the planet's rings onto its atmosphere, Cassini data show.
By | Published: October 4, 2018 | Last updated on May 18, 2023
SaturnRingSmallParticles
Saturn’s rings are made of individual particles, from dust grains to car- and house-sized boulders. This image shows the density of the rings: Purple indicates regions with larger particles (bigger than about 2 inches), while green and blue indicate regions with smaller particles (less than 2 inches).
NASA/JPL
Before it plunged into the atmosphere of Saturn on its final death dive, the Cassini spacecraft made 22 orbits of the planet that followed a path no probe had taken before: It flew between the massive planet and its rings. During those final orbits, Cassini’s Ion and Neutral Mass Spectrometer (INMS) spotted water ice and complex organic molecules flowing from the rings to the atmosphere of the planet: ring rain. But it turns out, “ring rain is more like a ring downpour,” according to Hunter Waite of Southwest Research Institute (SwRI), lead author of a paper on the findings published October 4 in Science.

The rain itself wasn’t a surprise. “Based on previous work, scientists expected water was raining from the rings into Saturn’s atmosphere,” said study co-author Kelly Miller, also of SwRI. She added that the spacecraft was even oriented in a way to intentionally use its radio antenna “as an umbrella to protect it from debris.” What was a surprise, though, was the amount of rain — it was “way faster than anyone thought,” said Waite. The data clock the downpour at a rate of 22,000 pounds (10,000 kilograms) of material falling onto the planet from its rings per second.

That’s a lot of rain.

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Ring rain occurs as particles from the rings fall onto Saturn. Following the analysis of Cassini data, researchers were surprised at the amount of complex organic molecules in the rain.
Image Courtesy of NASA/JPL/SwRI
Unexpected complex chemistry

According to INMS measurements, the rain includes molecular hydrogen, water, and even butane and propane, which are considered “complex organics” by astronomers because of the amount of carbon atoms they contain. While hydrogen is a major component of Saturn’s atmosphere and the researchers expected to see it (and water) raining down from the rings to the planet, the complex organic molecules falling alongside them were less expected.

INMS also measured variations in “rainfall” between one orbit and the next. This could mean that certain areas of the D ring, the planet’s innermost ring, are either physically different and generate varying amounts of rain, or that the overall rainfall simply changes rates over time.

The team worked carefully for months to confirm their results before releasing the study. Due to the high speed of the spacecraft as it swooped between planet and rings, INMS could sense the particles because they hit the detector and shattered. But that high speed not only made the results trickier to interpret, it also means that some of the compounds detected in the rain are only fragments, and the picture Cassini gathered might be incomplete.

Regardless, “It was worth it,” Waite said. He explained that such a huge amount of material flowing from the D ring to the planet likely plays a role in the chemistry of Saturn’s atmosphere. Furthermore, the outflow of material means that the D right might be regularly replenished in the same way by the next ring out, the C ring.

Saturn’s ring system is unique in our solar system, and it’s likely not done surprising us yet. Even a year after its final transmission, Cassini’s data still holds a wealth of information just waiting to be uncovered, and planetary scientists remain hard at work, looking for what new discovery might appear next.