Yes there will be N2 from Air, but as I have said, O2 is uniquely paramagnetic for the elements at the bottom of the table and it aggregates the EVOs that can transmute matter in a way that N2 is less good at and O2 is something that will come from the water and the Air.
This worked
E1 in ('O') and A2 = 180 and E3 in ('Si', 'Ca', 'V', 'Cr', 'Fe', 'Cu', 'Zn', 'Zr') order by MeV desc
What is it that you are after?
I think I'm sorta getting this.
Is this something of interest to you?
N14 ... W184 MeV = 123.464448
Using (code limit 202 for ID in the buffer)
e1 in ( 'n' ) and a2 in ( 184 ) and e2 < > 'Os' and a4 > = 100 and MeV > 115 order by MeV desc limit 202
[Keeping Osmium out because we only want W184 (the common isotope).]
This link *might* still work if you want to see it.
https://www.nanosoft.co.nz/results/select_*_from_TwoToTwoAllNewPlus_where_e1inlbnrbanda2inlb184rbande2ltgtOsanda4gteq100andMeVgt115ByMeVDescLimit202.html
If there's O2 in there there might also be N2, no? And this packs a little more punch if I understand how this works.
Yes there will be N2 from Air, but as I have said, O2 is uniquely paramagnetic for the elements at the bottom of the table and it aggregates the EVOs that can transmute matter in a way that N2 is less good at and O2 is something that will come from the water and the Air.
I just chose it as indicative.
Just trying to duplicate your results.
Also seeing how the spreadsheet is set up. Lots of experimenting. Even cheaper than ULTR !! :-)
Gotta run. I'll probably bug you again later...