000001723 001__ 1723
000001723 005__ 20250922143404.0
000001723 0247_ $$2doi$$a10.6082/uchicago.1723
000001723 041__ $$aeng
000001723 245__ $$aViolating Bell’s Inequality with Remotely-Connected Superconducting Qubits
000001723 260__ $$bUniversity of Chicago
000001723 269__ $$a2019-03
000001723 300__ $$a200
000001723 336__ $$aDissertation
000001723 502__ $$bPh.D.
000001723 520__ $$aQuantum communication relies on the efficient generation of entanglement between remote quantum nodes, due to entanglement’s key role in achieving and verifying secure communications. Remote entanglement has been realized using a number of different

probabilistic schemes, but deterministic remote entanglement has only recently been demonstrated, using a variety of superconducting circuit approaches. However, the deterministic violation of a Bell inequality, a strong measure of quantum correlation, has not

to date been demonstrated in a superconducting quantum communication architecture, in part because achieving sufficiently strong correlation requires fast and accurate control of the emission and capture of the entangling photons. Here we present a simple and

robust architecture for achieving this benchmark result in a superconducting system.
000001723 650__ $$aQuantum physics
000001723 653__ $$aBell's inequality
000001723 653__ $$amultimode
000001723 653__ $$aquantum state transfer
000001723 653__ $$asuperconducting qubit
000001723 653__ $$atunable coupling
000001723 690__ $$aPritzker School of Molecular Engineering
000001723 7001_ $$aZhong, Youpeng$$uUniversity of Chicago
000001723 72012 $$aAndrew N. Cleland
000001723 72014 $$aDavid Awschalom
000001723 72014 $$aAashish Clerk
000001723 72014 $$aDavid Schuster
000001723 8564_ $$908852982-573a-4dbe-a4ca-368b0acf3fc9$$ePublic$$s22208056$$uhttps://knowledge.uchicago.edu/record/1723/files/Zhong_uchicago_0330D_14694.pdf
000001723 909CO $$ooai:uchicago.tind.io:1723$$pDissertations$$pGLOBAL_SET
000001723 983__ $$aDissertation