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Electromagnetically accelerated magnesium ultramicroparticles formed from a cryoslurry of Mg with argon gas create an ultra high reaction surface area reactant as well as catalyst combining that with methane CH4 from natural gas or methane hydrates causes the CH4 to avoid full oxidation which then causes methane methane linkages to create higher molecular mass liquid fuel alkanes The materials are all ultraaffordable as well as situ with magnesium from magnesium chloride at seawater, methane hydrates, argon from air Another approach is just to put a ultrahighsurface area Mg metal form on something that is kind of like a van de graaf generator. The ultra high availability of the electrons, so active they actually create plasma filaments cause a blend of CH4 with O2 to partially react which then causes some of the partially reacted CH3 or even CH2 radicals to react with each other creating longer alkanes to produce liquid fuel. Also think of the PVNRT graph space opportunities as well; along with varying CH4 O2 ratios there are also spatial streams say from light compression to greater compression to lighter compression which is strongly reminiscent of a completely different thing that could be modified to become a liquid fuel from methane reactor Modifying gas turbines to create liquid alkanes At the concentric depths of a Gas turbine different PVNRT areas are arranged; what would the effect of having the metal that part of the concentric fans are made of be if they were made of catalytic or reactive metals preferably this would create partial oxidation products that are actually longer alkanes while also producing electricity from CH4 at a gas turbine, this creates a wider range of fiscal applicabilities of function
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What part of the phase diagram is this occurring at
If you think of a floating ultramacroparticulate of magnesium that is ultra active as an ion from the RF electromagnetic energy this could be a fluidized bed or gas.
Also, the ultravelocitization described at the handyphone produced images could be a swirl or linear directed like a mass driver moving Mg particles.
As a liquid petroleum fuel from methane technology this was originally a different technology, what could move more rapidly than O2 autooxidizing, thus the thought is that EM motionized ultra reactive yet superaffordable metal that would react with the oxygen first
At CH4 to liquid fuel applications the partial oxidation of methane that permits methane to link to methane, some words like methanocation , gel (as compared with aerosol or MgAr colloid cryoslurry), or carbocationish are conceptual approximations rather than actual quasiaqueous specifics. Varying the ratio of O2 to CH4 would certainly have effects, When using ocean water magnesium, as well as air argon with methane hydrates, the meaning of things like Magnesium nitrates is unknown.
Another approach is just to put a ultrahighsurface area Mg metal form on something that is kind of
like a van de graaf generator. The ultra high availability of the electrons, so active they actually create plasma filaments cause a blend of CH4 with O2 to partially react which then causes some of the partially reacted CH3 or even CH2 radicals to react with each other creating longer alkanes to
produce liquid fuel.
Also think of the PVNRT graph space opportunities as well; along with varying CH4 O2 ratios there are also spatial streams say from light compression to greater compression to lighter compression which is strongly reminiscent of a completely different
thing that could be modified to become a liquid fuel from methane reactor
Modifying gas turbines to create liquid alkanes
At the concentric depths of a Gas turbine different PVNRT areas are arranged; what would the
effect of having the metal that part of the concentric fans are made of be if they were
made of catalytic or reactive metals preferably this would create partial oxidation
products that are actually longer alkanes while also producing electricity from CH4 at a gas turbine,
this creates a wider range of fiscal applicabilities of function
