[+]wuliheron0 points0 points0 points
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[–]wuliheron0 points
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This is such fantastic research that could be applicable to a variety of other technology currently in development. What is required is the analog logic for generating entanglement faster with, for example, some already exploring self-assembling quantum computer technology. Combining the right materials with the right amount of complexity into a resilient system would be the equivalent of a high tech abacus that can conflate the identity of its input and output, energy and information, possibly even cheaply and at room temperature. Making it quantum mechanical and capable of entanglement, simply adds more dimensions, while dimension squeezing using pseudo two dimensional objects and even time crystals is becoming commonplace. It could be possible to generate entanglement systematically in four rudimentary ways that overlap to some extent, and figuring out how that works could produce a theory of everything.
Physicists are already in the process of using AI to rapidly predict quantum states and will be applying the same idea to condensed matter physics soon. Long range forces have proven every bit as important as short range ones for phase transitions, implying an underlying supersymmetry and systems logic the AI can search for. The question is not whether these model reality, but how useful are the models.
[–] wuliheron ago (edited ago)
This is such fantastic research that could be applicable to a variety of other technology currently in development. What is required is the analog logic for generating entanglement faster with, for example, some already exploring self-assembling quantum computer technology. Combining the right materials with the right amount of complexity into a resilient system would be the equivalent of a high tech abacus that can conflate the identity of its input and output, energy and information, possibly even cheaply and at room temperature. Making it quantum mechanical and capable of entanglement, simply adds more dimensions, while dimension squeezing using pseudo two dimensional objects and even time crystals is becoming commonplace. It could be possible to generate entanglement systematically in four rudimentary ways that overlap to some extent, and figuring out how that works could produce a theory of everything.
Physicists are already in the process of using AI to rapidly predict quantum states and will be applying the same idea to condensed matter physics soon. Long range forces have proven every bit as important as short range ones for phase transitions, implying an underlying supersymmetry and systems logic the AI can search for. The question is not whether these model reality, but how useful are the models.