to be proven by Aspect et al.’ s experiments in Paris in 1982.
9. J. S. Bell, ‘On the Einstein-Poldolsky-Rosen paradox’, Physics, 1964; 1: 195–200.
10. S. Ghosh et al., ‘Entangled quantum state of magnetic dipoles’, Nature, 2003; 435: 48–51.
11. Details of Vedral’s views and experiments the result of multiple interviews, February, October and December 2005.
12. C. Arnesen et al., ‘Thermal and magnetic entanglement in the 1D Heisenberg Model’, Physical Review Letters, 2001; 87: 017901.
13. V. Vedral, ‘Entanglement hits the big time’, Nature, 2003; 425: 28–9.
14. T. Durt, interview with author, April 26, 2005.
15. B. Reznik, ‘Entanglement from the vacuum’, Foundations of Physics, 2003; 33: 167–76; Michael Brooks, ‘Entanglement: The weirdest link’, New Scientist, 2004; 181 (2440): 32.
16. John D. Barrow, The Book of Nothing, London: Jonathan Cape, 2000: 216.
17. Erwin Laszlo, The Interconnected Universe: Conceptual Foundations of Transdiscipinary Unified Theory, Singapore: World Scientific Publishing, 1995: 28.
18. A. C. Clarke, ‘When will the real space age begin?’ Ad Astra, May–June 1996; 13–15.
19. Harold Puthoff, ‘Ground state of hydrogen as a zero-point-fluctuation-determined state’, Physical Review D, 1987; 35: 3266.
20. B. Haisch, Alfonso Rueda and H. E. Puthoff, ‘Inertia as a zero-point-field Lorentz force’, Physical Review A, 1994; 49 (2): 678–94; Bernhard Haisch, Alfonso Rueda and H. E. Puthoff, ‘Physics of the zero-point field: implications for inertia, gravitation and mass’, Speculations in Science and Technology, 1997; 20: 99–114.
21. Various interviews with Hal Puthoff, 1999–2000.
22. Reznik, ‘Entanglement from the vacuum’, op. cit.
23. McTaggart, The Field, op. cit.: 35–6.
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IN 1951, AT THE AGE OF SEVEN, Gary Schwartz made a remarkable discovery. He had been trying to get a good picture on the family’s television set. The recently acquired black and white Magnavox set encased behind the doors of its boxed walnut console fascinated him, not because of the people in the moving pictures so much as the means by which they arrived in his living room in the first place. The mechanisms of the relatively new invention remained a mystery, even to most adults. Television, like any other electrical gadget, was something the precocious child longed to take apart and understand. This passion had already found expression with the worn-out radios given to him by his grandfather. Ignatz Schwartz sold replacement tubes for televisions and radios in his drug store in Great Neck, Long Island, and those that were beyond repair were handed over to his grandson to disassemble. In a corner of Gary’s bedroom lay a mass of experimental debris – tubes, resistors and the carcasses of radios heaped on the cosmetic display racks he had borrowed from his grandfather – the first signs of what would become a lifelong fascination with electronics.
Gary knew that the way you twisted the rabbit-ear antenna on top of the television would determine the clarity of the picture. His father had explained that television sets were powered by something invisible, similar to radio waves, that flew through the air and were somehow translated into an image. Gary had even carried out some rudimentary experiments. When you stood somewhere between the antenna and the television, you could make the picture go away. When you touched the antenna in certain ways, you made the picture clearer.
One day, on a whim, Gary unscrewed the antenna and placed his finger on the screw where the cable had been. What had been a mass of squiggles and static noise on the screen suddenly coalesced into a perfect image. Even at that young age, he had understood that he had witnessed something extraordinary about human beings: his body was acting like a television antenna, a receiver of this invisible information. He tried the same experiment with a radio – substituting his finger for the antenna, and the same thing happened. Something in the makeup of a person was not unlike the rabbit ears that helped produce his television image. He too was a receiver of invisible information, with the ability to pick up signals transmitted across time and space.
Until he was 15, however, he could not visualize what these signals were made of. He had learned to play the electric guitar and had often wondered what unseen influences allowed the instrument to create different sounds. He could play the same note, middle C, and yet produce more of a treble or bass sound, depending on which way he turned the knob. How was it possible that a single note could sound so different? For a science project, he created multiple-track recordings of his music and then located a company in upstate New York that had equipment designed to analyse the frequency of sound. When he fed his recordings into the equipment, it quickly deconstructed the notes down to their essence. Each note registered as a batch of squiggles across the screen of the cathode-ray tube in front of him – a complex mix of hundreds of frequencies representing a blend of overtones that would subtly change when he turned the knob to treble or bass. He knew that these frequencies were waves, represented on the monitor as a sideways S, or sine curve, like a skipping rope held at both ends and wriggled, and that they had periodic oscillations, or fluctuations, similar to the waves on Long Island Sound. Every time he spoke, he knew he generated similar frequencies through his voice. He remembered his early television experiments and wondered whether a field of energy pulsated inside him and shared a kinship with sound waves.1
Gary’s childhood experiments may have been rudimentary,