SPEAKER_04

So the magnesium, and I did an atomic mapping of my piece of silicon down to a level of where it's like 99.999% silicon.

And so one piece of it had magnesium ratios that were earth normal.

These were impurities, let's say.

The other piece were way off earth normal.

So for instance, anywhere on earth, if you look at the ratios of what the three magnesium isotopes are, 24, 25, 26, it should be like 80%, 11%, 9% more or less.

And anywhere in our solar system, that's more or less what the values should be of the ratios.

And that has to do with stellar evolution and how radioactive compounds might decompose to whatever.

But we got this ratio that was just way, way off.

So by luck, I came across a postdoc at Stanford.

And he and a graduate student, they're both in applied physics, who are interested in UAP.

And I said, I've got these ratios.

What do you think it means?

And so they looked at the ratios, the weird one, and they said, well, let's do some calculations.

And so it turns out that the ratios that we have could have been generated from normal magnesium ratios if you exposed normal magnesium ratios to a neutron source for 900 years at the level of an atomic bomb every few seconds.

Okay.

So it's like I'm looking, and this data is literally two weeks old.

But the calculations are math.

So you're like, okay, well, where and how, you know, the chance of getting that number correct on three things is low, you know, to put it mildly.

But to say that you had exposed these things to that kind of a neutron source means something interesting, right?

So, again, it doesn't prove anything other than that the result is mathematically and materially true, right?