, Rapid accretion and 587 early core formation on asteroids and the terrestrial planets from Hf-W 588 chronometry, Nature, vol.418, pp.952-955, 2002.
, Late forma-590 tion and prolonged differentiation of the Moon inferred from W isotopes in 591 lunar metals, Nature, vol.450, pp.1206-1209, 2007.
, fluid dynamics of core formation, Origin of the Earth, vol.593, pp.231-249, 1990.
, Experiments on turbulent metal-595 silicate mixing in a magma ocean, Earth Planet. Sci. Lett, vol.310, pp.303-313, 2011.
, Turbulent metal -silicate mixing, 598 fragmentation, and equilibration in magma oceans, Earth Planet. Sci. Lett, vol.599, pp.274-287, 2014.
, Experiments on the fragmentation 601 of a buoyant liquid volume in another liquid, Fluid Mech, vol.749, p.478518, 2014.
, Laboratory 604 experiments on the breakup of liquid metal diapirs, Earth Planet. Sci
, , vol.403, p.236245, 2014.
, Experiments on fragmentation and thermo-607 chemical exchanges during planetary core formation, Phys. Earth Planet
, Satellite-sized planetesimals and lunar 610 origin, Icarus, vol.24, p.611, 1975.
, Core formation by giant impacts, ICARUS, vol.612, pp.326-346, 1992.
, Thermo-mechanical 614 adjustment after impacts during planetary growth, Geophys. Res. Lett, vol.615, pp.24201-24205, 2007.
, Early earth differentiation
, Sci. Lett, vol.225, pp.253-269, 2004.
, A model of 619 metal-silicate separation on growing planets. Earth and Planetary Science 620 Letters, vol.287, pp.353-362, 2009.
, Differentiated planetesimal impacts in a 622 terrestrial magma ocean: fate of the iron core, Earth Planet. Sci. Lett, vol.623, p.2433, 2016.
, The terrestrial late veneer from 625 core disruption of a lunar-sized impactor, Earth and Planetary Science, vol.626, p.2532, 2017.
, Mecha-628 nisms of metal-silicate equilibration in the terrestrial magma ocean, Earth 629 and Planet. Sci. Lett, vol.205, pp.239-255, 2003.
, Direct numerical simulation of an 631 iron rain in the magma ocean, GEOPHYSICAL RESEARCH, vol.115, p.1404, 2010.
, Turbulent mixing of metal and silicate during 636 planet accretion and interpretation of the hf-w chronometer
, Sci. Lett, vol.295, pp.177-186, 2010.
, Dubuffet, vol.639
, Compositional and thermal equilibration of par-640
, ticles, drops, and diapirs in geophysical flows, Geochem. Geophys. Geosyst, vol.641, p.12, 2011.
, Viscosity of mgsio3 liquid at earth? mantle 643 conditions : Implications for an early magma ocean, Science, vol.328, p.2010
, Transition from spherical cap to toroidal 646 bubbles, Phys. Fluids, vol.18, p.52102, 2006.
, Three-dimensional 648 simulations of vortex ring formation from falling drops in an immiscible 649 viscous liquid, Chem. Engng Japan, vol.42, p.648655, 2009.
, The sensitivity of 651 drop motion due to the density and viscosity ratio, Phys. Fluids, vol.22, p.72102, 2010.
, Inuence of the viscosity 654 ratio on drop dynamics and breakup for a drop rising in an immiscible 655 low-viscosity liquid, Fluid Mech, vol.752, p.383409, 2014.
, The buoyancy-driven motion of a single skirted 657
, Dynamics 660 and stability of an iron drop falling in a magma ocean, Phys. Earth Planet
, , vol.289, pp.75-89, 2019.
, Application of the level set 663 method for multi-phase flow computation in fusion engineering, Fusion 664 Engineering and Design, vol.81, p.15211526, 2006.
, Simulation of droplet impingement 666 on a solid surface by the level set method, vol.667, 2014.
, Small-scale metal/silicate equilibration during 669 core formation: The inuence of stretching enhanced diusion on mixing, Journal of Geophysical Research : Solid Earth, p.671, 2018.
, Formation of the earths core, 672 treatise on geophysics evolution of the earth, vol.9, pp.43-79, 2015.
, Mantle values of thermal conductivity and the geotherm 675 from phonon lifetimes, SCIENCE, vol.283, 1999.
, Direct shock compression exper-677 iments on premolten forsteriteand progress toward a consistent high-678 pressure equationof state for cao-mgo-al2o3-sio2-feo liquids, JOURNAL 679 OF GEOPHYSICAL RESEARCH: SOLID EARTH, vol.118, pp.5738-5752, 2013.
, , p.681
, The p-v-t equation of state and 684 thermodynamic properties of liquid iron, Journal of Geophysical Research: 685 Solid Earth, vol.119, pp.240-252, 2014.
, Use of breakup time data and velocity history 687 data to predict the maximum size of stable fragments for acceleration-688 induced breakup of a liquid drop, Multiphase Flow, vol.13, p.689, 1987.
, Single -drop fragmentation determines size 690 distribution of rain drops, Nat. Phys, vol.5, p.697702, 2009.
, Sec-692 ondary breakup of drops at moderate weber numbers: Eect of density ratio 693 and reynolds numbe, Int. J. Multiphase Flow, vol.117, p.2541, 2019.
, The mathematics of diffusion, p.695
, , 1975.
, Redefined cubic b-splines collocation method 697 for solving convectiondiffusion equations, Applied Mathematical Modelling, vol.698, pp.5555-5573, 2012.
,
, Iron 701 diapirs entrain silicates to the core and initiate thermochemical plumes, Nature Communications, vol.702, 2018.
, Diapirism in the earth's mantle: Experiments on the motion 704 of a hot sphere in a fluid with temperature-dependent viscosity, Journal of 705 Volcanology and Geothermal Research, vol.16, pp.221-245, 1983.
, On the penetration of a hot diapir through 707 a strongly temperature-dependent viscosity medium, Geophysical Journal 708 International, vol.83, p.657681, 1985.
, The effect of pressure on partitioning of ni 710 and co between silicate and iron-rich metal liquids: a diamond-anvil cell 711 study, Earth Planet. Sci. Lett, vol.209, p.245255, 2003.