Hal Puthoff
👤 PersonAppearances Over Time
Podcast Appearances
No, haven't. God, don't you want to? Well, I sure would like to do that, but... But that's still... We had this discussion earlier about, you know, for example, the row viewing or quantum entanglement or, you know, what's going on in our physics that we don't understand that these kinds of things can be happening. And you'll be interested to know that...
No, haven't. God, don't you want to? Well, I sure would like to do that, but... But that's still... We had this discussion earlier about, you know, for example, the row viewing or quantum entanglement or, you know, what's going on in our physics that we don't understand that these kinds of things can be happening. And you'll be interested to know that...
No, haven't. God, don't you want to? Well, I sure would like to do that, but... But that's still... We had this discussion earlier about, you know, for example, the row viewing or quantum entanglement or, you know, what's going on in our physics that we don't understand that these kinds of things can be happening. And you'll be interested to know that...
someone you know, John Paul DiGiorgio, and I are in partnership to explore a new means of communication, quantum communications. And so I'm actually now at this point directly involved in a program to examine quantum communications. And so it turns out that whereas ordinary electromagnetic communications, you know, can't get through barriers, metal door or whatever. Well, why is that?
someone you know, John Paul DiGiorgio, and I are in partnership to explore a new means of communication, quantum communications. And so I'm actually now at this point directly involved in a program to examine quantum communications. And so it turns out that whereas ordinary electromagnetic communications, you know, can't get through barriers, metal door or whatever. Well, why is that?
someone you know, John Paul DiGiorgio, and I are in partnership to explore a new means of communication, quantum communications. And so I'm actually now at this point directly involved in a program to examine quantum communications. And so it turns out that whereas ordinary electromagnetic communications, you know, can't get through barriers, metal door or whatever. Well, why is that?
It's because the electromagnetic signal, when it gets to the metal door, the electric and magnetic field generate counteracting effects and so the signal can't get through.
It's because the electromagnetic signal, when it gets to the metal door, the electric and magnetic field generate counteracting effects and so the signal can't get through.
It's because the electromagnetic signal, when it gets to the metal door, the electric and magnetic field generate counteracting effects and so the signal can't get through.
So it turned out that some years ago when I was digging around to try to find out how to explain unusual effects, I dug deeper into electromagnetism down into the quantum levels and recognized that there are some additional quantum processes where you could end up suppressing the electric and magnetic fields, but you would still have a quantum signal, which in principle could get through anything.
So it turned out that some years ago when I was digging around to try to find out how to explain unusual effects, I dug deeper into electromagnetism down into the quantum levels and recognized that there are some additional quantum processes where you could end up suppressing the electric and magnetic fields, but you would still have a quantum signal, which in principle could get through anything.
So it turned out that some years ago when I was digging around to try to find out how to explain unusual effects, I dug deeper into electromagnetism down into the quantum levels and recognized that there are some additional quantum processes where you could end up suppressing the electric and magnetic fields, but you would still have a quantum signal, which in principle could get through anything.
barriers. And so that would mean, okay, if that's the case, then you could communicate to submarines. So whereas the salt water is sufficiently conductive, the electromagnetic signal can't get down there and communicate. If you are able to pull out the electric and magnetic components, but you still have an underlying quantum aspect to it, you could get through.
barriers. And so that would mean, okay, if that's the case, then you could communicate to submarines. So whereas the salt water is sufficiently conductive, the electromagnetic signal can't get down there and communicate. If you are able to pull out the electric and magnetic components, but you still have an underlying quantum aspect to it, you could get through.
barriers. And so that would mean, okay, if that's the case, then you could communicate to submarines. So whereas the salt water is sufficiently conductive, the electromagnetic signal can't get down there and communicate. If you are able to pull out the electric and magnetic components, but you still have an underlying quantum aspect to it, you could get through.
Or same thing with, you know, spaceships. You know, when our spaceships came back from, when the Apollo spaceships came back, once they started in our atmosphere and are surrounded by plasma, we have this period where there's no communication. Well, for the very reason that electromagnetic signals can't get through charged plasmas. But this quantum communication aspect could.
Or same thing with, you know, spaceships. You know, when our spaceships came back from, when the Apollo spaceships came back, once they started in our atmosphere and are surrounded by plasma, we have this period where there's no communication. Well, for the very reason that electromagnetic signals can't get through charged plasmas. But this quantum communication aspect could.
Or same thing with, you know, spaceships. You know, when our spaceships came back from, when the Apollo spaceships came back, once they started in our atmosphere and are surrounded by plasma, we have this period where there's no communication. Well, for the very reason that electromagnetic signals can't get through charged plasmas. But this quantum communication aspect could.