For the wisdom of this world is foolishness with God.
1 Corinthians 3:19
"Secular planetary scientists have a skeleton key that unlocks any planetary mystery: the BFH.A “BFH” (big freaking hammer) is the jocular acronym for the most useful tool in a repairman’s toolkit. When something won’t budge, hit it with the BFH. If it breaks, it needed fixing anyway. That’s the thinking of the less nuanced problem-solver. The problem with a BFH is that when it’s your only tool, you tend to see everything as a nail.
The BFH for the astrobiologist or secular planetologist is the “impact hypothesis.” Since design is
Phos for us: One essential element for life on earth is phosphorus. Unfortunately, it tends to be locked up in rocks. NASA’s Astrobiology Magazine sets up the problem in order to justify wielding the BFH:
Phosphorus is one of life’s most vital components, but often goes unheralded. It helps form the backbone of the long chains of nucleotides that create RNA and DNA; it is part of the phospholipids in cell membranes; and is a building block of the coenzyme used as an energy carrier in cells, adenosine triphosphate (ATP).
Yet the majority of phosphorus on Earth is found in the form of inert phosphates that are insoluble in water and are generally unable to react with organic molecules. This appears at odds with phosphorus’ ubiquity in biochemistry, so how did phosphorus end up being critical to life?
Another hypothesis stated on PhysOrg tries to make phosphorus available via Miller-type spark-discharge processes that “could” have produced urea as an intermediate. This article resurrects the Darwin “warm little pond” meme. The scenario relies on special concentrations of salts and ions in specific locales without intelligent lab researchers adding them as needed. Nothing was said about keeping the phosphate ions from getting locked up in rocks again, once conditions change.
Carbon for us: Another essential element for life is carbon. Once again, Astrobiology Magazine appeals to the BFH for special delivery of this vital ingredient; only this time, the hammer is really big: “Earth’s carbon points to planetary smashup.” The impactor delivering carbon was as big as the planet Mercury, astrobiologists at Rice University are claiming. “Research by Rice University Earth scientists suggests that virtually all of Earth’s life-giving carbon could have come from a collision about 4.4 billion years ago between Earth and an embryonic planet similar to Mercury.” This must have been after the Mars-sized BFH that formed Earth’s moon. Or maybe the Rice guys didn’t think about that. Anyway, here is the setup:
“One popular idea has been that volatile elements like carbon, sulfur, nitrogen and hydrogen were added after Earth’s core finished forming,” said Li, who is now a staff scientist at Guangzhou Institute of Geochemistry, Chinese Academy of Sciences. “Any of those elements that fell to Earth in meteorites and comets more than about 100 million years after the solar system formed could have avoided the intense heat of the magma ocean that covered Earth up to that point."
“The problem with that idea is that while it can account for the abundance of many of these elements, there are no known meteorites that would produce the ratio of volatile elements in the silicate portion of our planet,” Li said.
Vesta luck: The BFH “scenario” works all over the solar system, not just at Earth. The asteroid Vesta, for instance has unusual amounts of the mineral olivine. Where did it come from? At Icarus, planetary scientists wielded the BFH once again: “Olivine on Vesta as exogenous contaminants brought by impacts: Constraints from modeling Vesta’s collisional history and from impact simulations.” Here’s the justification for the scenario:
The survival of asteroid Vesta during the violent early history of the Solar System is a pivotal constraint on theories of planetary formation. Particularly important from this perspective is the amount of olivine excavated from the vestan mantle by impacts, as this constrains both the interior structure of Vesta and the number of major impacts the asteroid suffered during its life. The NASA Dawn mission revealed that olivine is present on Vesta’s surface in limited quantities, concentrated in small patches at a handful of sites not associated with the two large impact basins Rheasilvia and Veneneia. The first detections were interpreted as the result of the excavation of endogenous olivine, even if the depth at which the detected olivine originated was a matter of debate. Later works raised instead the possibility that the olivine had an exogenous origin, based on the geologic and spectral features of the deposits. In this work, we quantitatively explore the proposed scenario of a exogenous origin for the detected vestan olivine to investigate whether its presence on Vesta can be explained as a natural outcome of the collisional history of the asteroid over the last one or more billion years.
To work effectively, the BFH requires use of another tool in the planetary scientist’s toolkit. That’s the Magic Wand that speaks, in a Sagan-like tone, saying “billions and billions of years.” CEH
