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January 2019
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  1. CFN Colloquium

    4 pm, CFN, Bldg 735, 2nd Floor Seminar Room

    Hosted by: Deyu Lu

    Solving correlated Fermi systems is a problem of ubiquitous importance in the fields of chemistry, materials science and fundamental interactions. Quantum computers can help addressing this type of challenges, provided that descriptions of Fermi systems are loaded onto a set of qubits. In this talk I will review methods to represent Fermi quantum states and interactions onto a set of qubits, how to optimize mapping procedures, and how these methods are used to perform computations on quantum hardware. I will then introduce connections between such mappings and stabilizer codes, showing that adequate encodings can account for the correction of single-qubit errors. Finally, I will show how the tools presented can have an impact on classical numerical methods.

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  1. JAN

    31

    Thursday

    CFN Colloquium

    4 pm, CFN, Bldg 735, Seminar Room 2nd Floor

    Thursday, January 31, 2019, 4:00 pm

    Hosted by: Deyu Lu (CFN) / Michael McGuigan (CSI)

    Solving correlated Fermi systems is a problem of ubiquitous importance in the fields of chemistry, materials science and fundamental interactions. Quantum computers can help addressing this type of challenges, provided that descriptions of Fermi systems are loaded onto a set of qubits. In this talk I will review methods to represent Fermi quantum states and interactions onto a set of qubits, how to optimize mapping procedures, and how these methods are used to perform computations on quantum hardware. I will then introduce connections between such mappings and stabilizer codes, showing that adequate encodings can account for the correction of single-qubit errors. Finally, I will show how the tools presented can have an impact on classical numerical methods.

  1. JAN

    31

    Thursday

    CFN Colloquium

    ""Fermi systems and quantum computing""

    Presented by Antonio Mezzacapo, Theory of Quantum Computing and Information, IBM T.J. Watson Research Center

    4 pm, CFN, Bldg 735, Seminar Room 2nd Floor

    Thursday, January 31, 2019, 4:00 pm

    Hosted by: Deyu Lu (CFN) / Michael McGuigan (CSI)

    Solving correlated Fermi systems is a problem of ubiquitous importance in the fields of chemistry, materials science and fundamental interactions. Quantum computers can help addressing this type of challenges, provided that descriptions of Fermi systems are loaded onto a set of qubits. In this talk I will review methods to represent Fermi quantum states and interactions onto a set of qubits, how to optimize mapping procedures, and how these methods are used to perform computations on quantum hardware. I will then introduce connections between such mappings and stabilizer codes, showing that adequate encodings can account for the correction of single-qubit errors. Finally, I will show how the tools presented can have an impact on classical numerical methods.

  2. FEB

    14

    Thursday

    CFN Colloquium

    "TBD"

    Presented by Dr. Andrea Alu, CUNY ASRC, NYC

    4 pm, CFN, Bldg 735, Seminar Room, 2nd Floor

    Thursday, February 14, 2019, 4:00 pm

    Hosted by: Donald DiMarzio, PhD

    TBD