Tuesday, January 17, 2006

Maybe In Our Lifetime?

So he isn't Zefram Cochrane or Isaac Asimov, I don't really care as long as there is the possibility of traveling to another solar system while I am still young enough to enjoy it.

New Scientist SPACE - Features - Take a leap into hyperspace: "Quantum theory describes the realm of the very small - atoms, electrons and elementary particles - while general relativity deals with gravity. The two theories are immensely successful in their separate spheres. The clash arises when it comes to describing the basic structure of space. In general relativity, space-time is an active, malleable fabric. It has four dimensions - three of space and one of time - that deform when masses are placed in them. In Einstein's formulation, the force of gravity is a result of the deformation of these dimensions. Quantum theory, on the other hand, demands that space is a fixed and passive stage, something simply there for particles to exist on. It also suggests that space itself must somehow be made up of discrete, quantum elements.

In the early 1950s, Heim began to rewrite the equations of general relativity in a quantum framework. He drew on Einstein's idea that the gravitational force emerges from the dimensions of space and time, but suggested that all fundamental forces, including electromagnetism, might emerge from a new, different set of dimensions. Originally he had four extra dimensions, but he discarded two of them believing that they did not produce any forces, and settled for adding a new two-dimensional 'sub-space' onto Einstein's four-dimensional space-time.

In Heim's six-dimensional world, the forces of gravity and electromagnetism are coupled together. Even in our familiar four-dimensional world, we can see a link between the two forces through the behaviour of fundamental particles such as the electron. An electron has both mass and charge. When an electron falls under the pull of gravity its moving electric charge creates a magnetic field. And if you use an electromagnetic field to accelerate an electron you move the gravitational field associated with its mass. But in the four dimensions we know, you cannot change the strength of gravity simply by cranking up the electromagnetic field.

In Heim's view of space and time, this limitation disappears. He claimed it is possible to convert electromagnetic energy into gravitational and back again, and speculated that a rotating magnetic field could reduce the influence of gravity on a spacecraft enough for it to take off.

When he presented his idea in public in 1957, he became an instant celebrity. Wernher von Braun, the German engineer who at the time was leading the Saturn rocket programme that later launched astronauts to the moon, approached Heim about his work and asked whether the expensive Saturn rockets were worthwhile. And in a letter in 1964, the German relativity theorist Pascual Jordan, who had worked with the distinguished physicists Max Born and Werner Heisenberg and was a member of the Nobel committee, told Heim that his plan was so important "that its successful experimental treatment would without doubt make the researcher a candidate for the Nobel prize".
Or, we could be on our way to a tesseract. A real one, not the one from A Wrinkle in Time.
From this, Dröscher claims, you can derive the four forces known in physics: the gravitational and electromagnetic forces, and the strong and weak nuclear forces. But there's more to it than that. "If Heim's picture is to make sense," Dröscher says, "we are forced to postulate two more fundamental forces." These are, Dröscher claims, related to the familiar gravitational force: one is a repulsive anti-gravity similar to the dark energy that appears to be causing the universe's expansion to accelerate. And the other might be used to accelerate a spacecraft without any rocket fuel.

This force is a result of the interaction of Heim's fifth and sixth dimensions and the extra dimensions that Dröscher introduced. It produces pairs of "gravitophotons", particles that mediate the interconversion of electromagnetic and gravitational energy. Dröscher teamed up with Jochem Häuser, a physicist and professor of computer science at the University of Applied Sciences in Salzgitter, Germany, to turn the theoretical framework into a proposal for an experimental test. The paper they produced, "Guidelines for a space propulsion device based on Heim's quantum theory", is what won the AIAA's award last year.

Claims of the possibility of "gravity reduction" or "anti-gravity" induced by magnetic fields have been investigated by NASA before (New Scientist, 12 January 2002, p 24). But this one, Dröscher insists, is different. "Our theory is not about anti-gravity. It's about completely new fields with new properties," he says. And he and Häuser have suggested an experiment to prove it. Please, just not on the planet we live on. I'd hate for us to go blowing backwards out of the solar plane. You know that equal and opposite reaction thing.

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