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Experimental method measures quantum coherence, the ability of being in 2 states at once by Staff Writers Barcelona, Spain (SPX) Jul 31, 2017
One of the main principles of quantum physics is the superposition of states. Systems are simultaneously in different states, i.e. "alive and dead" at the same time such as Schrodinger's cat, until someone measures them and the system opts for one of the possibilities. As long as the superposition lasts the system is said to be in a coherent state. In real systems, a set of diverse elemental particles or atoms existing in a state of superposition, for example, in different positions simultaneously, with different levels of energy, or with two opposite spins (rotating trajectories), are said to have weak coherence: the superposition is broken easily by the vibrations associated with temperature and environmental interactions. Researchers from the UAB Department of Physics and the Indian Institute of Science, Education and Research Kolkata propose a new way of measuring the robustness of the quantum coherence of a superimposed state. The method is based on the measurement of the visibility of interference fringes, a figure formed by alternate dark and intense stripes similar to that of a zebra, produced when two coherent states coincide. According to UAB researcher Andreas Winter, "The existence of quantum superpositions is at the heart of the non-classical nature of quantum physics. It manifests itself by producing interference patterns in interferometric experiments. "We show that each visibility parameter of the interference pattern, such as the difference between maximums and minimums in intensity, gives rise to a measure of coherence. The study thus connects the recently burgeoning, but hitherto rather abstract resource theory of coherence, to concrete and physically relevant observations." The scientists, experts in information quantum theory, study the intrinsic properties of quantum mechanics such as entanglement, uncertainty, superposition, indeterminism and interference, to be used as resources in quantum information processing, the foundation of future quantum computers.
New York NY (SPX) Jul 27, 2017 While the charge and spin properties of electrons are widely utilized in modern day technologies such as transistors and memories, another aspect of the subatomic particle has long remained uncharted. This is the "valley" property which has potential for realizing a new class of technology termed "valleytronics" - similar to electronics (charge) and spintronics (spin). This property arises ... read more Related Links Universitat Autonoma de Barcelona Understanding Time and Space
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