According to replies in this Russian-language thread, the napthyl fuel burned in the Soyuz 2 launch vehicle is kerosene with fewer aromatic compounds and more napthenes. There's no mention of boron compounds.
If the fuel contained significant amounts of boron it would be easy to tell- the exhaust flames would be bright green.
Quote from: lrk on 05/21/2021 02:54 pmIf the fuel contained significant amounts of boron it would be easy to tell- the exhaust flames would be bright green. Can we find out what the Isp of a combination of Boron Trifluoride, Ethane (20% Boron Trifluoride, 80% Ethane), and Oxygen would be?
Use of Oxygen and Naphthyl gives a vacuum Isp of about 370 seconds. Could the complete elimination of aromatic compounds and the increase of napthenes explain such a high specific impulse?
I ran the free online CEA on liquid ethane with and without 20 mol % BF3. Chamber pressure 300 bar, shifting equilibrium, probably a few other parameters I'm not sophisticated enough to include. Output files attached. Inclusion of BF3 increases specific impulse by about 10 s at optimum O/F. Optimum mixture ratio is slightly more "fuel" rich presumably due to inclusion of oxidizing material in the fuel.Since I know I'm not sophisticated enough to assure accurate real-world numbers with CEA I quote the difference of 10 s, which should be much more robust to setup choices on my part. So whatever is possible with liquid ethane as fuel you can do approximately that much better with BF3 included, if it really is soluble.
They were the hype of the late 50's for both B-70 Valkyrie and early rocketry, to the point so ill-advised people started speculating on stocks of that stuff. Then it was found it was not only toxic, it also let ultra-hard deposits on rocket and turbojet combustion chamber; that were nearly impossible to clean up.