Solid H<sub>2</sub> in the interstellar medium

Füglistaler, Andreas; Pfenniger, D.

doi:10.1051/0004-6361/201731739

Cited by 24 publications

(21 citation statements)

References 29 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Moreover, Seligman & Laughlin (2020) confirmed that H 2 O could not be the dominant accelerant and ruled-out CO 2 . H 2 ice was discussed as a possible constituent of 'Oumuamua by Füglistaler & Pfenniger (2018) and reconciled with the energy balance of the non-gravitational acceleration by Seligman & Laughlin (2020). Molecular nitrogen ice was demonstrated to be consistent with the non-Keplerian trajectory by .…”

mentioning

confidence: 88%

On The Spin Dynamics of Elongated Minor Bodies with Applications to a Possible Solar System Analogue Composition for `Oumuamua

Seligman,

Levine,

Cabot

et al. 2021

Preprint

View full text Add to dashboard Cite

The first interstellar object, 1I/2017 U1 ('Oumuamua), exhibited several unique properties, including an extreme aspect ratio, a lack of typical cometary volatiles, and a deviation from a Keplerian trajectory. Several authors have hypothesized that the non-gravitational acceleration was caused by either cometary outgassing or radiation pressure. Here, we investigate the spin dynamics of 'Oumuamua under the action of high surface area fractional activity and radiation pressure. We demonstrate that a series of transient jets that migrate across the illuminated surface will not produce a secular increase in the spin rate. We produce 3D tumbling simulations that approximate the dynamics of a surface covering jet, and show that the resulting synthetic light curve and periodogram are reasonably consistent with the observations. Moreover, we demonstrate that radiation pressure also produces a steady spin-state. While carbon monoxide (CO) has been dismissed as a possible accelerant because of its non-detection in emission by Spitzer, we show that outgassing from a surface characterized by a modest covering fraction of CO ice can satisfy the non-ballistic dynamics for a plausible range of assumed bulk densities and surface albedos. Spitzer upper limits on CO emission are, however, inconsistent with the CO production necessary to provide the acceleration. Nonetheless, an ad hoc but physically plausible explanation is that the activity level varied greatly during the time that the trajectory was monitored. We reproduce the astrometric analysis presented in Micheli et al. (2018), and verify that the non-gravitational acceleration was consistent with stochastic changes in outgassing.

show abstract

mentioning

confidence: 88%

On The Spin Dynamics of Elongated Minor Bodies with Applications to a Possible Solar System Analogue Composition for `Oumuamua

Seligman,

Levine,

Cabot

et al. 2021

Preprint

View full text Add to dashboard Cite

show abstract

“…As shown previously, water ice radiolysis produces large quantities of H 2 in the first meters of the subsurface. At cometary nucleus temperature, H 2 sublimates rapidly (Greenberg & de Jong 1969;Füglistaler & Pfenniger 2018). Due to the high porosity of the nucleus, it is thus likely that a significant part outgasses from the comet.…”

Section: Impact Of Gcr On Chemical Compositionmentioning

confidence: 99%

The Effect of Cosmic Rays on Cometary Nuclei. II. Impact on Ice Composition and Structure

Maggiolo

Gronoff

Cessateur

et al. 2020

ApJ

View full text Add to dashboard Cite

Since their formation in the protosolar nebula some ∼4.5 billion years ago, comets are in storage in cold distant regions of the solar system, the Kuiper Belt/scattered disk or Oort Cloud. Therefore, they have been considered as mostly unaltered samples of the protosolar nebula. However, a significant dose of energy is deposited by galactic cosmic rays (GCRs) into the outermost tens of meters of cometary nuclei during their stay in the Oort Cloud or Kuiper Belt. We investigate the impact of energy deposition by GCRs on cometary nuclei. We use experimental results from laboratory experiments and the energy deposition by GCRs estimated by Gronoff et al. (2020), to discuss the depth down to which the cometary nucleus is altered by GCRs. We show that GCRs do not significantly change the isotopic composition of cometary material but modify the chemical composition and the ice structure in the outer layers of the nucleus, which cannot be considered as pristine solar nebula material. We discuss the effect of the collisional history of comets on the distribution of processed material inside the nucleus and its implication on the observation of comets.

show abstract

“…Moreover, comets are expected to persist indefinitely in the galactic environment, and so it is surprising that the first-detected ISO had kinematics associated with an extremely young age. Füglistaler & Pfenniger (2018) raised the possibility that 'Oumuamua could be composed of H 2 ice. This hypothesis was further developed by Seligman & Laughlin (2020) who showed that solid hydrogen can plausibly explain 'Oumuamua's unusual properties.…”

Section: Introductionmentioning

confidence: 99%

Evidence Suggesting that 'Oumuamua is the ~30 Myr-old product of a Molecular Cloud

Hsieh,

Laughlin,

Arce

2021

Preprint

View full text Add to dashboard Cite

The appearance of interstellar objects (ISOs) in the Solar System -and specifically the arrival of 1I/'Oumuamua -points to a significant number density of free-floating bodies in the solar neighborhood. We review the details of 'Oumuamua's pre-encounter galactic orbit, which intersected the Solar System at very nearly its maximum vertical and radial excursion relative to the galactic plane. These kinematic features are strongly emblematic of nearby young stellar associations. We obtain an a-priori order-of-magnitude age estimate for 'Oumuamua by comparing its orbit to the orbits of 50,899 F-type stars drawn from Gaia DR2; a diffusion model then suggests a ∼ 35 Myr dynamical age. We compare 'Oumuamua's orbit with the trajectories of individual nearby moving groups, confirming that its motion is fully consistent with membership in the Carina (CAR) moving group with an age around 30 Myr. We conduct Monte Carlo simulations that trace the orbits of test particles ejected from the stars in the Carina association. The simulations indicate that in order to uniformly populate the ∼ 10 6 pc 3 volume occupied by CAR members with the inferred number density, n = 0.2 AU −3 , of ISOs implied by Pan-STARRS' detection of 'Oumuamua, the required ejection mass is M ∼ 500 M Jup per known star within the CAR association. This suggests that the Pan-STARRS observation is in significant tension with scenarios that posit 'Oumuamua's formation and ejection from a protostellar disk.

show abstract

Solid H₂ in the interstellar medium

Cited by 24 publications

References 29 publications

On The Spin Dynamics of Elongated Minor Bodies with Applications to a Possible Solar System Analogue Composition for `Oumuamua

On The Spin Dynamics of Elongated Minor Bodies with Applications to a Possible Solar System Analogue Composition for `Oumuamua

The Effect of Cosmic Rays on Cometary Nuclei. II. Impact on Ice Composition and Structure

Evidence Suggesting that 'Oumuamua is the ~30 Myr-old product of a Molecular Cloud

Contact Info

Product

Resources

About

Solid H2 in the interstellar medium

Cited by 24 publications

References 29 publications

On The Spin Dynamics of Elongated Minor Bodies with Applications to a Possible Solar System Analogue Composition for `Oumuamua

On The Spin Dynamics of Elongated Minor Bodies with Applications to a Possible Solar System Analogue Composition for `Oumuamua

The Effect of Cosmic Rays on Cometary Nuclei. II. Impact on Ice Composition and Structure

Evidence Suggesting that 'Oumuamua is the ~30 Myr-old product of a Molecular Cloud

Contact Info

Product

Resources

About

Solid H₂ in the interstellar medium