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Aerosols and hydrocarbons in the atmosphere of a white dwarf planet.

Created on 02 Jul 2026

Authors

Ryan J MacDonald, Christopher E O'Connor, Victoria A Boehm, E M May, David K Sing, Elijah Mullens, L C Mayorga, Trevor O Foote, Simon Blouin, Logan A Pearce, Nikole K Lewis, Jeff Valenti, Natasha E Batalha, Maura Lally, Joshua D Lothringer, Mark S Marley, Ishan Mishra, Susan E Mullally

Published in

Nature. Volume 655. Issue 8121. Pages 76-80. Epub Jul 01, 2026.

Abstract

Most stars, including our Sun, will one day evolve into red giants and, subsequently, white dwarfs. Several planet candidates have recently been identified orbiting white dwarfs1-4, demonstrating that planets can survive the stellar post-main-sequence stage intact. Little is known about the atmospheric composition of post-main-sequence planets, with the most evolved transiting planets with atmospheric detections so far orbiting subgiants5,6. Here we report an atmospheric detection for the white dwarf planet WD 1856 b, achieved through transmission spectroscopy with the James Webb Space Telescope (JWST) Near-Infrared Spectrograph (NIRSpec) PRISM. Our 0.5-5.0-μm spectrum reveals the presence of hydrocarbons (odds ratio of 167:1-5,377:1, with CH4 preferred at 17:1-30:1), aerosols (2 × 105:1-2 × 106:1) and thermal emission from the planetary nightside (2 × 1063:1-2 × 1073:1). Our spectral analysis constrains the mass of WD 1856 b to 4.3-10.9 MJ, finds a carbon-enriched atmosphere (with a CH4 abundance of approximately 7%) and an effective temperature exceeding the expected planetary equilibrium temperature (390-412 K versus 160 K). On the basis of cooling models, these results indicate that WD 1856 b underwent a migration-related reheating event 3.0-5.5 Gyr into the white dwarf phase, consistent with post-main-sequence tidal evolution to the present-day 0.02-AU circular orbit. Our results provide a window into the ultimate fate of giant planets orbiting stars with masses similar to our Sun.

PMID:
42387166
Bibliographic data and abstract were imported from PubMed on 02 Jul 2026.

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