Nitrogen transport in protoplanetary disks by ammonium salts: a possible origin of Jupiter's nitrogen enrichment

TL;DR

This paper proposes that ammonium salts in the solar nebula could have transported nitrogen to Jupiter, explaining its uniform nitrogen enrichment, through a model of salt dissociation, NH3 vapor production, and planetary core accretion.

Contribution

It introduces a novel mechanism involving ammonium salts for nitrogen delivery to Jupiter, addressing limitations of previous models based on amorphous ice transport.

Findings

Ammonium salts in dust can produce sufficient NH3 vapor to match Jupiter's nitrogen levels.

Salt-containing dust with 10-30 wt% ammonium salts effectively explains planetary nitrogen enrichment.

The model aligns with observed elemental compositions of Jupiter's atmosphere.

Abstract

Atmospheric compositions preserve the history of planet formation processes. Jupiter has the remarkable feature of being uniformly enriched in various elements compared to the Sun, including highly volatile elements such as nitrogen and noble gases. Radial transport of volatile species by amorphous ice in the solar nebula is one mechanism that explains Jupiter's volatile enrichment, but the low entrapment efficiency of nitrogen into amorphous ice is an issue. We propose an alternative mechanism of delivering nitrogen to Jupiter: radial transport of semi-volatile ammonium salts in the solar nebula. Ammonium salts have been identified in 67P/Churyumov-Gerasimenko and can potentially compensate for the comet's nitrogen depletion compared to the Sun. We simulate the radial transport and dissociation of ammonium salts carried by dust in a protoplanetary disk, followed by the accretion of the gas and NH$_3$ vapor by a protoplanet, as well as the delivery of nitrogen to the planetary atmosphere from the salt-containing planetary core that undergoes dilution. We find that when the dust contains 10-30 wt% ammonium salts, the production of NH$_3$ vapor in the inner disk (~ 3 au) by dissociated salts and the incorporation of the salt-derived NH$_3$ through core formation and subsequent gas accretion by the protoplanet result in a planetary nitrogen enrichment consistent with the observations of Jupiter. Ammonium salts may thus play a vital role in developing the atmospheric composition of planets forming in the inner disk. Combining our model with future observations of the bulk compositions and isotopes of comets and other primordial bodies will help to further elucidate the elemental transport to the gas giants and ice giants in the solar system.