Hal Puthoff

1628. 1628. So there are enough stories like that with lots of observers and the reporting under really excellent conditions. Okay. Now that guy didn't have a nuclear power pack on his back. So how did that happen?

1628. 1628. So there are enough stories like that with lots of observers and the reporting under really excellent conditions. Okay. Now that guy didn't have a nuclear power pack on his back. So how did that happen?

Well, the only thing I can think of in terms of the physics we know today would be that somehow the vacuum energy, which can be very high if you cohered it and if you made it nonrandom,

Well, the only thing I can think of in terms of the physics we know today would be that somehow the vacuum energy, which can be very high if you cohered it and if you made it nonrandom,

Well, the only thing I can think of in terms of the physics we know today would be that somehow the vacuum energy, which can be very high if you cohered it and if you made it nonrandom,

So since it's unknown, there's no way we would know how to tap it.

So since it's unknown, there's no way we would know how to tap it.

So since it's unknown, there's no way we would know how to tap it.

Right. And I have no way to connect the physics to it.

Right. And I have no way to connect the physics to it.

Right. And I have no way to connect the physics to it.

We tried to look into that. For example, Andrei Sakharov, a very famous Soviet physicist, said, you know, I don't think gravity is its own thing. I think really it's a manifestation of the underlying quantum fluctuations. And so I and some colleagues from Lockheed Martin and elsewhere kind of looked into that option. And, you know, if we're just sitting here talking and so on,

We tried to look into that. For example, Andrei Sakharov, a very famous Soviet physicist, said, you know, I don't think gravity is its own thing. I think really it's a manifestation of the underlying quantum fluctuations. And so I and some colleagues from Lockheed Martin and elsewhere kind of looked into that option. And, you know, if we're just sitting here talking and so on,

We tried to look into that. For example, Andrei Sakharov, a very famous Soviet physicist, said, you know, I don't think gravity is its own thing. I think really it's a manifestation of the underlying quantum fluctuations. And so I and some colleagues from Lockheed Martin and elsewhere kind of looked into that option. And, you know, if we're just sitting here talking and so on,

You know, the universe is full of quantum fluctuations. Why don't I notice it? On the other hand, if you get into your fast-moving car and you suddenly take off, you're pressed back in your seat. Well, what is it that's pressing you back? I mean, it isn't the wind. You've got a windshield and a cover.

You know, the universe is full of quantum fluctuations. Why don't I notice it? On the other hand, if you get into your fast-moving car and you suddenly take off, you're pressed back in your seat. Well, what is it that's pressing you back? I mean, it isn't the wind. You've got a windshield and a cover.

You know, the universe is full of quantum fluctuations. Why don't I notice it? On the other hand, if you get into your fast-moving car and you suddenly take off, you're pressed back in your seat. Well, what is it that's pressing you back? I mean, it isn't the wind. You've got a windshield and a cover.

Well, there's some modeling that says, well, maybe it's because if you try to accelerate through the vacuum fluctuations, it will push back on you. So that might be our first little touch that, okay, under conditions of acceleration, we do notice the background vacuum fluctuations. Well, says to a theorist, inertia and gravity are connected somehow.

Well, there's some modeling that says, well, maybe it's because if you try to accelerate through the vacuum fluctuations, it will push back on you. So that might be our first little touch that, okay, under conditions of acceleration, we do notice the background vacuum fluctuations. Well, says to a theorist, inertia and gravity are connected somehow.

Well, there's some modeling that says, well, maybe it's because if you try to accelerate through the vacuum fluctuations, it will push back on you. So that might be our first little touch that, okay, under conditions of acceleration, we do notice the background vacuum fluctuations. Well, says to a theorist, inertia and gravity are connected somehow.