First. Holmlid has deminstated that ultra dense matter can produce decay of nucleons. This generates lots of energy. In other words, Ultra dense matter may be a source of energy.
Next. this compression produced by gravity is sufficient to produce pressure to compress hydrogen, metal, metal compounds, hydrids, and water, to reach the 2.000.000 bar level. This is the level of pressure needed to reach the pressure level where ultra dense matter is formed. Finally, the quantum nature of the ultra dense matter can withstand energy production up to 90,000F and retain the capacity to generate energy through nucleon decay. This type matter is rugged enough to survive and supports geologic activity inside celestial bodies. Therefore, ultra dense matter could produce the energy that maintains geological activity within frozen planets and smaller bodies. For example the large moon of Pluto, Charon shows signs of geological activity, https://arstechnica.com/science/2019/03/craters-on-pluto-suggest-kuiper-belt-ate-its-smaller-bodies/ Regardless of where they looked, the same general trend was apparent: there weren't enough small craters. Above about 10km across, the rate of cratering is about what you'd expect for a smooth distribution of impactor sizes (meaning you expect fewer big objects). But below 10km, things drop rather dramatically. On Tue, Mar 26, 2019 at 11:26 PM <[email protected]> wrote: > In reply to Axil Axil's message of Tue, 26 Mar 2019 17:44:56 -0400: > Hi, > [snip] > >https://www.futurity.org/plasma-liquid-metal-physics-2003862/ > > > >All ultra dense metals including hydrogen and water retain quantum > behavior > >up to 90,000F > > > >This supports the idea that compressed matter is a heat source inside > >planets and other smaller bodies. > > How does it support this contention? > > Regards, > > > Robin van Spaandonk > > local asymmetry = temporary success > >
