The photosynthetic path is inspired by known photoaddition processes, for instance
http://www.orgsyn.org/orgsyn/prep.asp?prep=cv5p0528and despite having no experience for it, I dared to adapt the idea, so please take my proposal with all
due caution.
Photoaddition is praised to avoid cyclodimers, like cyclooctadiene from butadiene. Further, to let reactants add with one of a different kind, I imagine to
excite only one reactant through wavelength selectivity, and have the excited reactant less concentrated so it combines more probably with a different reactant, instead of dimerizing.
Excimer lamps exist with proper wavelengths. See for instance Iupac, Heraeus or others:
http://old.iupac.org/goldbook/ET07372.pdfhttp://www.heraeus-noblelight.com/en/products_1/uvprozesstechnik_1/uvp_excimer.aspx-
Xe2 radiates at 172nm, 900W consumption, perfect for
ethylene;
-
KrCl at 222nm, 3000W consumption, fits 1,3-
butadiene around 217nm;
- KrI 190nm, ArF 193nm and others are not catalogue parts.
Xe2 is said to offer up to
40% efficiency, good others
5 to 15%.
I plan
no sensitizer, since the lamps have the proper wavelength. This shall hopefully improve the light efficiency; the excimer lamps would then consume less electricity than 50k€/t used by the 7% efficient mercury lamp in the above cited photoaddition, which has 1/26 quantum efficiency. Stirring and permanent reactant feed shall improve also. Would a sensitizer improve or degrade the reaction selectivity? No idea. Maybe a wrong choice, or not.
Solvents widen too much the absorption wavelength peak, so
gases shall react. With light absorption of 15000/cm and 21000/cm for ethylene and butadiene in molar solution,
1mb of reactants would already absorb within 1cm, so
stir if using a higher partial pressure. The reactants can hence be
cold, nice against spontaneous polymerisation and leaks; operating near their (reduced pressure's) boiling point would let the
products condense away as they form. To widen absorption peaks by 2*5nm and fit the lamps, add about
10b of a nonreactive gas (nitrogen? Rare gas?) which must be pure for transparency. Mind absorption throughout light path!
----- To vinyl-cyclobutane
Excited butadiene reacts mainly with the more
abundent ethylene to make vinyl-cyclobutane; proportions can keep some divinyl-cyclobutane.
Alternately, excited ethylene reacts mainly with the more abundent vinyl-cyclobutane. This would produce more cyclobutane, which shall be controlled in a rocket fuel as it's volatile, so distill. Products separation within the reactor also gets less obvious.
----- To cyclobutyl-cyclobutane (Boctane)
Excited vinyl-cyclobutane (by KrI, ArF lamp?) reacts mainly with the more
abundent ethylene to make cyclobutyl-cyclobutane (Boctane).
Alternately, excited ethylene reacts mainly with the more abundent vinyl-cyclobutane. This would produce more cyclobutane.
The 1,2-trans-divinyl-cyclobutane fraction makes
dicyclobutyl-cyclobutane, which is denser than Boctane, less flammable, and could well improve the melting point, so
keep it in Boctane! Adjust its proportion through the gas partial pressures in the first cycloaddition.
Photo dimerization of vinyl-cyclobutane will also provide some dicyclobutyl-cyclobutane, possibly the 1,3 isomer whose mix should lower the melting point, welcome. Tune the gas partial pressures in the second cycloaddition.
----- Variants
I wish C=CC=C
butadiene is replaced by piperylene C=CC=CC, isoprene C=C(C)C=C or an other, or some mix. The product should offer a lower melting point, a higher flash point, and the reactants are less volatile if not more healthy and stable. Store cold.
Ethylene also can be replaced or mixed. A
blended product, from mixed reactants or through successive batches or both, uses to offer a lower melting point and viscosity.
Is the (substituted)
dicyclobutyl-cyclobutane alone better than Boctane? Denser and less flammable, but what melting point? It should be feasible from divinyl-cyclobutane (see Orgsyn's paper) and ethylene, or (1,3-?) from vinyl-cyclobutane. Or start from 3-methyl-hexatriene, available from rubber pyrolysis, which seems to cyclise less than hexatriene, and could have been the reactant to Syntin. Prefer blends as usual.
Divinyl-cyclobutane could be
cyclopropaned instead. Isomer of the old Syntin, same performance. Substitute and blend.
More distant enes in the reactant would make a product
more flexible and unsymmetric than Boctane. Less dense, but lower melting point. If the melting point improves enough, a third ring would regain density.
A bit of cyclobutane is acceptable in the fuel (cubane as well, thanks); excess might be sold, reverted to ethylene (in real time?), converted separately to Boctane if possible. Cyclobutene should be stripped and reverted to butadiene.
Xe2 lamps to produce cyclobutane could be interesting by themselves, even if not to make Boctane. It could even be possible on Mars; cyclobutane needs less hydrogen brought there than to produce methane from the atmosphere - though I'd instead burn hydrogen with local oxygen, or rather bring the propellants.
If exciting only ethylene, both steps might occur in the
same reactor... Or if providing light at both wavelengths for butadiene and vinyl-cyclobutane... Then, vinyl-cyclobutane must be gaseous and cyclobutyl-cyclobutane better liquid. Mind cyclobutane amount as well. Less easy to tune!
The inspiring paper at Orgsyn excites Michler's ketone around 336nm from medium-pressure mercury. Usable for vinyl-cyclobutane? Optimum
sunlight brings 4W/m2 between 336nm and 306nm.
Comments welcome!
Marc Schaefer, aka Enthalpy
ChemBuddy | 
Chem Reddit | 
Topic: Boctane (Read 54033 times)