Abstract
This study explores the delivery of phosphorus to the upper atmospheres of Earth, Mars, and Venus via the ablation of cosmic dust particles. Micron-size meteoritic particles were flash heated to temperatures as high as 2900 K in a Meteor Ablation Simulator (MASI), and the ablation of PO and Ca recorded simultaneously by laser induced fluorescence. Apatite grains were also ablated as a reference. The speciation of P in anhydrous chondritic porous Interplanetary Dust Particles was made by K-edge X-ray absorption near edge structure (XANES) spectroscopy, demonstrating that P mainly occurs in phosphate-like domains. A thermodynamic model of P in a silicate melt was then developed for inclusion in the Leeds Chemical Ablation Model (CABMOD). A Regular Solution model used to describe the distribution of P between molten stainless steel and a multicomponent slag is shown to provide the most accurate solution for a chondritic-composition, and reproduces satisfactorily the PO ablation profiles observed in the MASI. Meteoritic P is moderately volatile and ablates before refractory metals such as Ca; its ablation efficiency in the upper atmosphere is similar to Ni and Fe. The speciation of evaporated P depends significantly on the oxygen fugacity, and P should mainly be injected into planetary upper atmospheres as PO2, which will then likely undergo dissociation to PO (and possibly P) through hyperthermal collisions with air molecules. The global P ablation rates are estimated to be 0.017 t d−1 (tonnes per Earth day), 1.15 × 10−3 t d−1 and 0.024 t d−1 for Earth, Mars and Venus, respectively.
Highlights
Phosphorus, P, is one of the key biological elements, with compounds of phosphorus appearing profusely in living systems where they play a major role in many fundamental biochemical functions, including replication, information transfer, and metabolism (Macia, 2005)
The first objective of the present study was to explore the differential ablation of phosphorus using the Meteor ablation Simulator (MASI) (Bones et al, 2016; Gomez-Martín et al, 2017), an experimental setup that detects the evaporating metals from meteoritic samples by Laser-Induced Fluorescence (LIF)
K-edge (XANES) spectroscopy on interplanetary dust particles (IDPs) shows that P is mainly found in phosphate-like domains
Summary
Phosphorus, P, is one of the key biological elements, with compounds of phosphorus appearing profusely in living systems where they play a major role in many fundamental biochemical functions, including replication, information transfer, and metabolism (Macia, 2005). More reduced forms of P (oxidation state þ3) are, far more soluble, and as such have an improved bioavailability. Pasek (2008) investigated the direct delivery of P to the surface of the Earth in meteorites, which might undergo processing through aqueous phase chemistry. In their study, they demonstrate how phosphides, present as the mineral schreibersite in Pallasite iron nickel meteorites, can be oxidized in water to form several prebiotic P species. Iron nickel meteorites only make up around 1% of the total annual mass influx of exogenous material entering the Earth’s atmosphere, with interplanetary dust particles (IDPs) making up the other 99% (Plane et al, 2017). An alternative route to reduced forms of P has been proposed in the form of atmospheric processing of vaporized P atoms, which enter planetary
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