A Revision to the Outer Solar System
Neptune and Uranus may be better classified as “magma-ocean giants” rather than “ice giants.” A new study from researchers at the University of California proposes that these planets contain a well-mixed magma ocean with dissolved hydrogen—a structure that offers an alternative to the three-layer model of their interiors.
The Failure of the Ice Giant Paradigm
For years, astronomers categorized these worlds as ice giants. The long-standing hypothesis assumed a rocky core covered by a mantle of water, ammonia, and methane ices, with a hydrogen/helium atmosphere. Yet, scientists aren’t sure where the planets originally formed in the early solar system or the reason for their wildly chaotic magnetic fields.
Recent University of California simulations offer an alternative. By analyzing Kuiper Belt objects—which are thought to preserve evidence of the material in the outer Solar System where Uranus and Neptune formed—scientists found these bodies are composed primarily of rock rather than ice. This suggests the internal composition of Uranus and Neptune may be different than previous assumptions held.
Hydrogen Dissolved in Deep Magma
The research team developed an interior model to align with these observed properties. Their findings indicate that at high pressures, hydrogen gas can dissolve into magma.

Instead of the three-layer model, this process creates a well-mixed fluid at the bottom and a hydrogen-dominated envelope at the top. This mixing might help explain the density of Uranus and Neptune, which has traditionally been interpreted as evidence for an ice-rich interior.
New Frameworks for Distant Worlds
This shift extends beyond our own neighborhood. The “magma-ocean” theory provides a new framework for scientists to analyze sub-Neptune planets across the Milky Way, which have thus far remained a mystery. This model may finally clarify their internal structures.
Although the Voyager flyby confirmed the planets’ classification as ice giants, these findings offer a way to interpret the data. The magma-ocean model serves as an update to our knowledge of the interior structure of the two planets.
Quick Comparison of Interior Models
| Feature | Traditional "Ice Giant" Model | Proposed "Magma-Ocean" Model |
|---|---|---|
| Primary Mantle | Water, ammonia, and methane ice | Well-mixed magma with dissolved hydrogen |
| Composition Basis | Assumed ice-rich outer solar system | Rock-rich material (similar to Kuiper Belt) |
| Internal Structure | Three-layer (Core, Mantle, Atmosphere) | Well-mixed fluid interior |
| Density Explanation | Explained by presence of ices | Explained by hydrogen-magma mixing |