Jason Jorjani

But there were constant storms on it, electrical storms, typhoons. There was a lot of volcanic activity on this planet. And they basically concluded that they couldn't settle there without altering the planet, without terraforming it in some way to make it more habitable. So... This is a long conversation to have during a remote viewing session. Yeah, so they got all this out of him, right?

But there were constant storms on it, electrical storms, typhoons. There was a lot of volcanic activity on this planet. And they basically concluded that they couldn't settle there without altering the planet, without terraforming it in some way to make it more habitable. So... This is a long conversation to have during a remote viewing session. Yeah, so they got all this out of him, right?

I think those are all the important points. Very detailed. Yes. So now you put this next to what Dr. John Brandenburg discovered regarding Mars. Dr. Brandenburg, who I got to spend a few days with in New Mexico a number of years ago, he worked on the Clementine mission for NASA. And at one point he was working at Sandia Labs, which is where I think a lot of the nuclear weapons are designed.

I think those are all the important points. Very detailed. Yes. So now you put this next to what Dr. John Brandenburg discovered regarding Mars. Dr. Brandenburg, who I got to spend a few days with in New Mexico a number of years ago, he worked on the Clementine mission for NASA. And at one point he was working at Sandia Labs, which is where I think a lot of the nuclear weapons are designed.

I think those are all the important points. Very detailed. Yes. So now you put this next to what Dr. John Brandenburg discovered regarding Mars. Dr. Brandenburg, who I got to spend a few days with in New Mexico a number of years ago, he worked on the Clementine mission for NASA. And at one point he was working at Sandia Labs, which is where I think a lot of the nuclear weapons are designed.

Mm-hmm. And he was looking at isotopic data from Mars. So every planet has certain amount of isotopes of different materials and metals and so forth on it. Right. And apparently the isotopic ratio of xenon-129 is consistent across the entire solar system, except for on Mars and our thermonuclear test sites on Earth.

Mm-hmm. And he was looking at isotopic data from Mars. So every planet has certain amount of isotopes of different materials and metals and so forth on it. Right. And apparently the isotopic ratio of xenon-129 is consistent across the entire solar system, except for on Mars and our thermonuclear test sites on Earth.

Mm-hmm. And he was looking at isotopic data from Mars. So every planet has certain amount of isotopes of different materials and metals and so forth on it. Right. And apparently the isotopic ratio of xenon-129 is consistent across the entire solar system, except for on Mars and our thermonuclear test sites on Earth.

There's a deviation from the norm of the isotopic signature of xenon-129 at our thermonuclear test sites on Earth. And we find the same thing at Cydonia on Mars. Why is it different on nuclear test sites? Something happens when, and it has to be not an atomic bomb, but a thermonuclear bomb. When a thermonuclear bomb is detonated, that leaves a trace of xenon-129 in that area where...

There's a deviation from the norm of the isotopic signature of xenon-129 at our thermonuclear test sites on Earth. And we find the same thing at Cydonia on Mars. Why is it different on nuclear test sites? Something happens when, and it has to be not an atomic bomb, but a thermonuclear bomb. When a thermonuclear bomb is detonated, that leaves a trace of xenon-129 in that area where...

There's a deviation from the norm of the isotopic signature of xenon-129 at our thermonuclear test sites on Earth. And we find the same thing at Cydonia on Mars. Why is it different on nuclear test sites? Something happens when, and it has to be not an atomic bomb, but a thermonuclear bomb. When a thermonuclear bomb is detonated, that leaves a trace of xenon-129 in that area where...

which is not the normal, basically, distribution of that isotope that you would find on Earth or on any of the other rocky bodies in the solar system. And according to Brandenburg, it's a very distinct signature. It's unmistakable, and it's very specifically associated with thermonuclear weapons detonation.

which is not the normal, basically, distribution of that isotope that you would find on Earth or on any of the other rocky bodies in the solar system. And according to Brandenburg, it's a very distinct signature. It's unmistakable, and it's very specifically associated with thermonuclear weapons detonation.

which is not the normal, basically, distribution of that isotope that you would find on Earth or on any of the other rocky bodies in the solar system. And according to Brandenburg, it's a very distinct signature. It's unmistakable, and it's very specifically associated with thermonuclear weapons detonation.

Then, after he discussed this with one of the scientists at Sandia Labs, whose expertise is working on nuclear weapons... He checked for other isotopes, and he saw that the isotopic ratio of thorium and uranium was also off at Cydonia in a way that matched thermonuclear test sites.

Then, after he discussed this with one of the scientists at Sandia Labs, whose expertise is working on nuclear weapons... He checked for other isotopes, and he saw that the isotopic ratio of thorium and uranium was also off at Cydonia in a way that matched thermonuclear test sites.

Then, after he discussed this with one of the scientists at Sandia Labs, whose expertise is working on nuclear weapons... He checked for other isotopes, and he saw that the isotopic ratio of thorium and uranium was also off at Cydonia in a way that matched thermonuclear test sites.

And so he came to the conclusion that, and even did the math, like how many nukes would you have had to detonate in this place to produce this kind of a deviation? Turns out that an empire state building's worth of our highest yield thermonuclear warheads would have had to have been detonated there to produce this kind of isotopic signature.

And so he came to the conclusion that, and even did the math, like how many nukes would you have had to detonate in this place to produce this kind of a deviation? Turns out that an empire state building's worth of our highest yield thermonuclear warheads would have had to have been detonated there to produce this kind of isotopic signature.

And so he came to the conclusion that, and even did the math, like how many nukes would you have had to detonate in this place to produce this kind of a deviation? Turns out that an empire state building's worth of our highest yield thermonuclear warheads would have had to have been detonated there to produce this kind of isotopic signature.