Mercury's Protoplanetary Mass

Major element fractionation among chondrites has been discussed for decades as ratios relative to Si or Mg. Recently, by expressing ratios relative to Fe, I discovered a new relationship admitting the possibility that ordinary chondrite meteorites are derived from two components, a relatively oxidized and undifferentiated, primitive component and a somewhat differentiated, planetary component, with oxidation state like the highly reduced enstatite chondrites, which I suggested was identical to Mercury’s complement of “lost elements”. Here, on the basis of that relationship, I derive expressions, as a function of the mass of planet Mercury and the mass of its core, to estimate the mass of Mercury’s “lost elements”, the mass of Mercury’s “alloy and rock” protoplanetary core, and the mass of Mercury’s gaseous protoplanet. Although Mercury’s mass is well known, its core mass is not, being widely believed to be in the range of 70-80 percent of the planet mass. For a core mass of 75 percent, the mass of Mercury’s “lost elements” is about 1.32 times the mass of Mercury, the mass of the “alloy and rock” protoplanetary core is about 2.32 times the mass of Mercury, and the mass of the gaseous protoplanet of Mercury is about 700 times the mass of Mercury. Circumstantial evidence is presented in support of the supposition that Mercury’s complement of “lost elements” is identical to the planetary component of ordinary-chondrite-formation. Communications: [email protected] http://NuclearPlanet.com