Link Between LHC and Quantum Computing Revealed by Physicists
Physicists Professor Chris White from Queen Mary University of London and his twin brother Professor Martin White from the University of Adelaide have uncovered an unexpected link between the Large Hadron Collider (LHC) and the future of quantum computing. Their groundbreaking discovery sheds new light on the quantum property known as "magic," a crucial element in the development of quantum computers.
For years, scientists have aimed to harness the strange properties of quantum mechanics to create computers with far greater processing power than today's classical systems. "Magic" is a measure that indicates the difficulty of simulating a quantum system on a non-quantum computer. The higher the magic, the more necessary a quantum computer becomes to describe the system's behavior, making it a key factor in the advancement of quantum technology.
In their research, published in Physical Review D, the White brothers demonstrate that the LHC routinely generates "magic." By studying the behavior of top quarks, the heaviest known fundamental particles, they predict that these "magic top quarks" will be produced frequently at the collider. The amount of magic exhibited by these top quarks varies depending on their speed and direction of movement, both of which can be measured using the ATLAS and CMS detectors at the LHC.
This discovery opens new possibilities for understanding and enhancing magic in other quantum systems. Professor Chris White explains, "While entanglement has long been the focus of quantum research, our work explores how magic in top quarks could provide a better foundation for quantum computing."
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Professor Martin White adds, "We have shown that the LHC is capable of observing not only quantum entanglement but also more intricate quantum behaviors at unprecedented energy levels."
Quantum computers have the potential to revolutionize industries such as drug discovery and materials science. However, controlling quantum states effectively requires a deep understanding of magic, which plays a vital role in enabling this control. The White brothers’ research bridges the gap between quantum information theory and high-energy physics, offering new insights into the capabilities of quantum computers.
Their work underscores the LHC’s potential as a unique platform for exploring quantum theory, pushing the boundaries of what is possible in both quantum computing and high-energy physics.