The Volatile Composition and Activity Evolution of Main-Belt Comet   358P/PANSTARRS

Henry H. Hsieh; John W. Noonan; Michael S. P. Kelley; Dennis Bodewits,; Jana Pittichova; Audrey Thirouin; Marco Micheli; Matthew M. Knight; Michele; T. Bannister; Colin O. Chandler; Carrie E. Holt; Matthew J. Hopkins; Yaeji; Kim; Nicholas A. Moskovitz; William J. Oldroyd; Jack Patterson; Scott S.; Sheppard; Nicole Tan; Chadwick A. Trujillo; and Quanzhi Ye

arXiv:2411.07435·astro-ph.EP·November 13, 2024

The Volatile Composition and Activity Evolution of Main-Belt Comet 358P/PANSTARRS

Henry H. Hsieh, John W. Noonan, Michael S. P. Kelley, Dennis Bodewits,, Jana Pittichova, Audrey Thirouin, Marco Micheli, Matthew M. Knight, Michele, T. Bannister, Colin O. Chandler, Carrie E. Holt, Matthew J. Hopkins, Yaeji, Kim, Nicholas A. Moskovitz, William J. Oldroyd

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TL;DR

This study reports the first direct detection of water vapor from main-belt comet 358P/PANSTARRS using JWST, revealing sublimation-driven activity and providing insights into its composition, dust activity, and potential proxies for water production estimation.

Contribution

It provides the second direct detection of sublimation in a main-belt comet and analyzes its composition, dust activity, and morphology, advancing understanding of active asteroids.

Findings

01

Water vapor detected with a production rate of ~5x10^25 molecules/s.

02

Absence of hypervolatile species like CO2, CH3OH, and CO.

03

Dust activity shows a ~2.5x decline over two periods, with modeled asymmetric dust emission.

Abstract

We report the detection of water vapor associated with main-belt comet 358P/PANSTARRS on UT 2024 January 8-9 using the NIRSPEC instrument aboard JWST. We derive a water production rate of Q(H2O)=(5.0+/-0.2)x10^25 molecules/s, marking only the second direct detection of sublimation products of any kind from a main-belt comet, after 238P/Read. Similar to 238P, we find a remarkable absence of hypervolatile species, finding Q(CO2)<7.6x10^22 molecules/s, corresponding to Q(CO2)/Q(H2O)<0.2%. Upper limits on CH3OH and CO emission are also estimated. Photometry from ground-based observations show that the dust coma brightened and faded slowly over ~250 days in 2023-2024, consistent with photometric behavior observed in 2012-2013, but also indicate a ~2.5x decline in the dust production rate between these two periods. Dynamical dust modeling shows that the coma's morphology as imaged by JWST's…

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Taxonomy

TopicsAstro and Planetary Science · Isotope Analysis in Ecology