You might also be interested in the new scholar.google.com, which indexes articles in scholarly journals. For example, searching for Marvin Herndon on scholar.google.com turns up 11 results, some of which are publicly available.
Yeah, thanks again, someone pointed that out the other day, and I've been using it a little (and for a couple years or so, http://www.scirus.org/).
[nearly two years go by, and then...]
Thanks again to AZLiberty for that google scholar link. Here's one result of the search:
http://arxiv.org/abs/astro-ph/0408151
Solar System Formation Deduced from Observations of Matter
Authors: J. Marvin Herndon
Aspects of our Solar System's formation are deduced from observations of the chemical nature of matter. Massive cores are indicative of terrestrial-planet-composition-similarity to enstatite chondrite meteorites, whose highly-reduced state of oxidation may be thermodynamically stable in solar matter only at elevated temperatures and pressures. Consistent with the formation of Earth as envisioned by Arnold Eucken, thermodynamic considerations lead to the deduction that the terrestrial planets formed by liquid-condensation, raining out from the central regions of hot, gaseous protoplanets. The mass of protoplanetary-Earth, estimated to be 275-305mE, is similar to the mass of Jupiter, 318mE. Solar primordial gases and volatile elements were separated from the terrestrial planets early after planet formation, presumably during some super-luminous solar event, perhaps even before Mercury had completely formed. The pre-super-luminosity-terrestrial-planet mass distribution appears to be more consistent with observations of the close-in gas-giants of other planetary systems than the present-day-terrestrial-planet mass distribution. Although primarily formed by raining out from the centers of hot, gaseous protoplanets, evidence for the Earth and, by inference for the other terrestrial planets, suggests some outer, minor, secondary accretion of oxidized matter in the grain-growth accumulation way envisioned by George W. Wetherill. By contrast, the so-called "standard model" for our Solar System's formation has flawed conceptual underpinnings and would lead to the contradiction of terrestrial planets having insufficiently massive cores.