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Experimental realization of universal geometric quantum gates
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Experimental realization of universal geometric quantum gates with solid-state spins Experimental realization of a universal set of quantum logic gates is the central requirement for the implementation of a quantum computer. In an ¡®all-geometric¡¯ approach to quantum computation1, 2, the quantum gates are implemented using Berry phases3 and their non-Abelian extensions, holonomies4, from geometric transformation of quantum states in the Hilbert space5. Apart from its fundamental interest and rich mathematical structure, the geometric approach has some built-in noise-resilience features1, 2, 6, 7. On the experimental side, geometric phases and holonomies have been observed in thermal ensembles of liquid molecules using nuclear magnetic resonance8, 9; however, such systems are known to be non-scalable for the purposes of quantum computing10. There are proposals to implement geometric quantum computation in scalable experimental platforms such as trapped ions11, superconducting quantum bits12 and quantum dots13, and a recent experiment has realized geometric single-bit gates in a superconducting system14. Here we report the experimental realization of a universal set of geometric quantum gates using the solid-state spins of diamond nitrogen¨Cvacancy centres. These diamond defects provide a scalable experimental platform15, 16, 17 with the potential for room-temperature quantum computing16, 17, 18, 19, which has attracted strong interest in recent years20. Our experiment shows that all-geometric and potentially robust quantum computation can be realized with solid-state spin quantum bits, making use of recent advances in the coherent control of this system15, 16, 17, 18, 19, 20. |
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±¾ÄÚÈÝÓÉÓû§×ÔÖ÷·¢²¼£¬Èç¹ûÆäÄÚÈÝÉæ¼°µ½ÖªÊ¶²úȨÎÊÌ⣬ÆäÔðÈÎÔÚÓÚÓû§±¾ÈË£¬Èç¶Ô°æȨÓÐÒìÒ飬ÇëÁªÏµÓÊÏ䣺xiaomuchong@tal.com - ¸½¼þ 1 : Zu,_C.;_Wang,_W.-B.;_He,_L.;_Zhang,_W.-G.;_Dai,_C.-Y.;_Wang,_F.;_--_Experimental_realization_of_universal_geometric_quantum_gates_with_sol.pdf
2015-03-27 14:38:33, 682.9 K
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