Pluto has a global subsurface ocean despite of its small size and lack of strong tidal heating (Nimmo et al., 2016). To avoid freezing the subsurface ocean over 4.5 billion years, CH₄ clathrate layer with low thermal conductivity is suggested to be present at the base of the icy crust to thermally insulate the subsurface ocean (Kamata et al., 2019). However, the formation conditions, such as required temperature and CH₄ contents in oceanic water, are not well constrained. Given the high abundance of NH₃ in comets (Mumma and Charnley, 2011), and the occurrence of H₂O-NH₃ ice along extensional fracture (Cruikshank et al., 2019), Pluto's ocean may contain high concentrations of NH₃ in addition to CH₄. Although the presence of NH₃ in liquid can decrease the dissociation temperature of clathrate (Vu et al., 2014; Petuya et al., 2020), the formation conditions of CH₄ clathrate layer for the H₂O-CH₄-NH₃ system have been addressed experimentally at pressures less than 20 MPa (Petuya et al., 2020), which is far from the pressure conditions achieved in Pluto (e.g., 100–200 MPa: Kamata et al., 2019).
Here we performed molecular dynamics simulations to understand the formation conditions (i.e., temperature and CH₄ contents in liquid) of CH₄ clathrate. We investigated the stability of CH₄ clathrate coexisting with H₂O-NH₃-CH₄ fluids with different NH₃ and CH₄ concentrations at pressures of 20, 40, and 200 MPa and temperatures of 200–320 K. Our results show that dissociation temperatures of CH₄ clathrate monotonically increase with pressure and decrease with NH₃ concentration in liquid. For a given NH₃ concentration in liquid, the dissociation temperature at 200 MPa is systematically 18 ± 8 K higher than the dissociation temperature at 20 MPa. At the maximum NH₃ concentration in our simulation (30% NH₃ relative to H₂O in liquid), the dissociation temperature at 200 MPa is 293 ± 8 K, decreased from 312 K without NH₃ (Sloan and Koh, 2007). However, all the clathrate dissociation temperatures at 200 MPa are still above the melting point of H₂O-NH₃ mixtures, indicating that the clathrate layer is thermodynamically stable at the interface between the subsurface ocean and icy crust of Pluto. In the presentation, we will also report the required CH₄ concentration in liquid to stabilize CH₄ clathrate. Based on the required CH₄ concentrations as functions of pressure and NH₃ concentration, we will discuss formation timing of CH₄ clathrate layer on early Pluto and possibilities of replenishment of surface CH₄ through eruptions of the subsurface liquid on recent Pluto (Cruikshank et al., 2019; Martin and Binzel, 2021).