TY - JOUR
T1 - Thermal evolution of trans-Neptunian objects through observations of Centaurs with JWST
AU - Licandro, Javier
AU - Pinilla-Alonso, Noemí
AU - Holler, Bryan J.
AU - De Prá, Mário N.
AU - Melita, Mario
AU - de Souza Feliciano, Ana Carolina
AU - Brunetto, Rosario
AU - Guilbert-Lepoutre, Aurélie
AU - Hénault, Elsa
AU - Lorenzi, Vania
AU - Stansberry, John A.
AU - Schambeau, Charles A.
AU - Harvison, Brittany
AU - Pendleton, Yvonne J.
AU - Cruikshank, Dale P.
AU - Müller, Thomas
AU - McClure, Lucas
AU - Emery, Joshua P.
AU - Peixinho, Nuno
AU - Bannister, Michele T.
AU - Wong, Ian
N1 - Publisher Copyright:
© The Author(s), under exclusive licence to Springer Nature Limited 2024.
PY - 2025/2
Y1 - 2025/2
N2 - Centaurs are small bodies orbiting between Jupiter and Neptune and behave as an intermediate population between trans-Neptunian-belt objects and Jupiter-family comets. As such, their surface composition and evolutionary processes are key to understanding the Solar System’s history. However, the mechanisms driving their transformation and the impact of thermal processing on their surfaces remain open questions. Here we examined the surface properties of five Centaurs using the James Webb Space Telescope near-infrared spectrograph reflectance spectra (0.6–5.3 μm). They exhibit considerable diversity in surface composition. Our analysis indicates that Centaurs can be split into two main categories, which is also observed for trans-Neptunian objects: one group has surfaces composed of refractory materials with some water ice, whereas the other is dominated by carbon-based materials. Additionally, two of the five objects have primarily refractory surfaces with minimal volatiles, suggesting a high concentration of primitive, comet-like dust. We suggest that the observed Centaur surfaces reflect their transitional states, as they are shifting from being ice-rich bodies to progressively becoming more dominated by non-volatile materials as they approach the Sun. Such thermal processing may have changed the surface properties of other similar Solar System bodies, like comets, Jupiter trojans and D-type asteroids.
AB - Centaurs are small bodies orbiting between Jupiter and Neptune and behave as an intermediate population between trans-Neptunian-belt objects and Jupiter-family comets. As such, their surface composition and evolutionary processes are key to understanding the Solar System’s history. However, the mechanisms driving their transformation and the impact of thermal processing on their surfaces remain open questions. Here we examined the surface properties of five Centaurs using the James Webb Space Telescope near-infrared spectrograph reflectance spectra (0.6–5.3 μm). They exhibit considerable diversity in surface composition. Our analysis indicates that Centaurs can be split into two main categories, which is also observed for trans-Neptunian objects: one group has surfaces composed of refractory materials with some water ice, whereas the other is dominated by carbon-based materials. Additionally, two of the five objects have primarily refractory surfaces with minimal volatiles, suggesting a high concentration of primitive, comet-like dust. We suggest that the observed Centaur surfaces reflect their transitional states, as they are shifting from being ice-rich bodies to progressively becoming more dominated by non-volatile materials as they approach the Sun. Such thermal processing may have changed the surface properties of other similar Solar System bodies, like comets, Jupiter trojans and D-type asteroids.
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U2 - 10.1038/s41550-024-02417-2
DO - 10.1038/s41550-024-02417-2
M3 - Article
AN - SCOPUS:85212513428
SN - 2397-3366
VL - 9
SP - 245
EP - 251
JO - Nature Astronomy
JF - Nature Astronomy
IS - 2
ER -