Massive cores make hot planets

Mordasini, C · 2013 · DOI 10.1051/0004-6361/201321617

2 Pith papers cite this work. Polarity classification is still indexing.

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Direct Images of CO2 Absorption in the Atmosphere of a Super-Jupiter: Enhanced Metallicity Suggestive of Formation in a Disk

astro-ph.EP · 2026-04-10 · unverdicted · novelty 7.0

Direct imaging reveals enhanced metallicity and aligned orbit in 29 Cyg b, supporting protoplanetary disk formation near the deuterium burning limit.

Giant Planet Formation by Disk Instability

astro-ph.EP · 2026-04-10 · unverdicted · novelty 2.0

The disk instability model remains viable for explaining giant planets that form early, at large orbital distances, and around M-dwarf stars, supported by updated simulations and observations.

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Direct Images of CO2 Absorption in the Atmosphere of a Super-Jupiter: Enhanced Metallicity Suggestive of Formation in a Disk astro-ph.EP · 2026-04-10 · unverdicted · none · ref 100
Direct imaging reveals enhanced metallicity and aligned orbit in 29 Cyg b, supporting protoplanetary disk formation near the deuterium burning limit.
Giant Planet Formation by Disk Instability astro-ph.EP · 2026-04-10 · unverdicted · none · ref 61
The disk instability model remains viable for explaining giant planets that form early, at large orbital distances, and around M-dwarf stars, supported by updated simulations and observations.

Massive cores make hot planets

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