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JWST reveals a strange sulfur world unlike any planet we know

Date:

March 17, 2026

Source:

University of Oxford

Summary:

Astronomers have identified a strange new kind of exoplanet that challenges how scientists classify worlds beyond our Solar System. The planet, L 98-59 d, appears to contain a vast ocean of molten rock beneath its surface that traps large amounts of sulfur deep inside. Observations from the James Webb Space Telescope revealed unusual sulfur-rich gases in its atmosphere and a surprisingly low density for its size.

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FULL STORY

An artist’s impression of L 98-59 d. Credit: Mark A. Garlick / markgarlick.com

A research team led by the University of Oxford has uncovered evidence for a previously unknown kind of planet beyond our Solar System -- one that locks away large quantities of sulfur deep inside a long lasting ocean of molten rock. The results were published on March 16 in Nature Astronomy.

The world, called L 98-59 d (an exoplanet, meaning it orbits a star outside our Solar System), circles a small red star about 35 light-years from Earth. Data from the James Webb Space Telescope (JWST) and ground based observatories revealed something unusual. For a planet about 1.6 times the size of Earth, it has a surprisingly low density and an atmosphere rich in hydrogen sulfide.

A Planet That Defies Classification

Until now, scientists would have grouped a planet like L 98-59 d into one of two categories. It could be a rocky "gas-dwarf" with a hydrogen dominated atmosphere, or a water rich world covered by deep oceans and ice.

New evidence shows it fits neither category. Instead, L 98-59 d appears to belong to a completely different class of planet dominated by heavy sulfur compounds.

A Global Magma Ocean Beneath the Surface

To understand this unusual world, researchers from the University of Oxford, the University of Groningen, the University of Leeds and ETH Zurich used advanced computer simulations to trace its evolution from shortly after formation to today, spanning nearly five billion years. By combining telescope observations with detailed models of planetary interiors and atmospheres, they were able to infer what is happening deep inside the planet.

Their findings suggest that L 98-59 d has a mantle made of molten silicate, similar to lava on Earth. Beneath its surface lies a vast magma ocean extending thousands of kilometers deep. This enormous reservoir allows the planet to trap large amounts of sulfur within its interior over long periods of time.

The magma ocean also helps maintain a thick hydrogen rich atmosphere that contains sulfur bearing gases such as hydrogen sulfide (H2S). Normally, radiation from the host star would gradually strip these gases away into space through X-ray driven processes.

Sulfur Cycling Between Interior and Atmosphere

Over billions of years, ongoing chemical exchanges between the molten interior and the atmosphere have shaped the planet's current appearance. These interactions explain the unusual signals detected by telescopes.

Researchers suggest that L 98-59 d may be the first identified example of a broader population of gas rich sulfur dominated planets that sustain long lived magma oceans. If that is the case, it points to a much wider variety of planetary types across the galaxy than previously recognized.

Lead author Dr. Harrison Nicholls (Department of Physics, University of Oxford) said: "This discovery suggests that the categories astronomers currently use to describe small planets may be too simple. While this molten planet is unlikely to support life, it reflects the wide diversity of the worlds which exist beyond the Solar System. We may then ask: what other types of planet are waiting to be uncovered?"

How Sulfur Shapes the Atmosphere

JWST observations from 2024 detected sulfur dioxide along with other sulfur gases high in the upper atmosphere of L 98-59 d. According to the team's models, these gases form when ultraviolet radiation from the host star, the red dwarf L 98-59, drives chemical reactions.

At the same time, the magma ocean below acts as a massive storage system for volatile materials, absorbing and releasing gases over billions of years after the planet formed. This combination of deep interior storage and ultraviolet driven chemistry explains the planet's distinctive properties.

Simulations indicate that L 98-59 d likely formed with a large supply of volatile material and may once have resembled a larger sub-Neptune type planet. Over time, it cooled, lost part of its atmosphere, and became smaller.

Scientists note that magma oceans are thought to be the initial state of all rocky planets (including the Earth and Mars). Studying these environments on distant worlds can provide insight into the earliest stages of our own planet's history.

Reconstructing Alien Worlds With Models

Co-author Professor Raymond Pierrehu