Quantum Entanglement Detector

According to quantum field theory, even a vacuum is filled with electromagnetic waves at different wavelengths. The Casimir effect measures the existence of these waves between two extremely close parallel plates of a Casimir device. As the plates get closer together some electromagnetic waves are excluded from between them because their wavelength no longer "fits." Of course, outside the device electromagnetic waves of all wavelengths are still viable, and these external waves will have greater energy than the waves between the plates. The net result is a measurable force between the plates dependent on the distance between them.
 
Used aboard a wormhole (jump) drive ship the Casimir device shows that when an object is transported or teleported through the wormhole the net effect is a weakening of the Casimir force. It is as if longer wavelength electromagnetic waves have been diminished. This effect is a direct consequence of the “atomizing” of spacetime. In effect spacetime is breaking down affecting larger masses and longer wavelength EM waves first as a result of the loss of entanglement in the area of the wormhole mouth.

To pass anything other than qubits through a wormhole the object must be entangled with the nearside wormhole mouth. In turn this will entangle it with the wormhole mouth on the far side. Each atom of the object must undergo this entanglement, and each atom uses a qubit to do so. A vast amount of entangled qubits are being used which the Casimir device can measure . . .

Source:
Wormhole Drive Engineering, 1st Edition by Dr. Franklin Benjamin
Copyright 3001 A.D. - Appendix 2, Pg. 779
A Casimir Device As An Entanglement Detector

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