Large Uncertainties in the Thermodynamics of Phosphorus (III) Oxide (P4O6) Have Significant Implications for Phosphorus Species in Planetary Atmospheres

Abstract

Phosphorus (III) oxide (P4O6) has been suggested to be a major component of the gas phase phosphorus chemistry in the atmospheres of gas giant planets and of Venus. However, P4O6's proposed role is based on thermodynamic modeling, itself based on values for the free energy of formation of P4O6 estimated from limited experimental data. Values of the standard Gibbs free energy of formation ((g)) of P4O6 in the literature differ by up to ~656 kJ/mol, a huge range. Depending on which value is assumed, P4O6 may either be the majority phosphorus species present or be completely absent from modeled atmospheres. Here, we critically review the literature thermodynamic values and compare their predictions to observed constraints on P4O6 geochemistry. We conclude that the widely used values from the NIST/JANAF database are almost certainly too low (predicting that P4O6 is more stable than is plausible). We show that, regardless of the value of (g) for P4O6 assumed, the formation of phosphine from P4O6 in the Venusian atmosphere is thermodynamically unfavorable. We conclude that there is a need for more robust data on both the thermodynamics of phosphorus chemistry for astronomical and geological modeling in general and for understanding the atmosphere of Venus and the gas giant planets in particular.