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Physics Fellowship Program

The RIKEN BNL Research Center offers a Fellow system at Brookhaven's Relativistic Heavy Ion Collider (RHIC) allowing joint appointments with universities and research laboratories throughout the world, enabling talented researchers to hold tenure track positions at their home institution as well as a Fellow position with the Center.

This system was established to increase the research potential of the Center and to disseminate its research activities and results. To date, nine RHIC Physics Fellows have received the U.S. Department of Energy Outstanding Junior Investigator Award and over 50 Fellows have received tenure at their home institutions since the inception of the program.

Institutions interested in initiating a new RHIC Physics Fellow position may obtain details on how to proceed by contacting Maureen McNeill-Shea, 1(631) 344-2758.

RBRC Research Groups


D. Kharzeev, Group Leader

This group conducts QCD related research that includes heavy ion physics, the quark gluon plasma, color glass condensate and hard QCD/spin physics.


T. Izubuchi, Group Leader

This group's mission is to solve the dynamics of QCD from first principle lattice simulations using in-house computer resources.


Y. Akiba, Group Leader

This group studies the spin structure of the proton via polarized p+p collisions at RHIC as well as the properties of quark gluon plasma.

The RIKEN BNL Research Center is part of Brookhaven's Nuclear & Particle Physics Directorate.

There are no conferences scheduled at this time.

  1. APR



    RIKEN Lunch Seminar

    "Partons from the Path-Integral Formalism of the Hadronic Tensor"

    Presented by Keh-Fei Liu, University of Kentucky

    12 pm, Building 510, Room 2-160

    Thursday, April 25, 2019, 12:00 pm

    Hosted by: Yuta Kikuchi

  2. MAY



    RIKEN Lunch Seminar

    "he Chiral Qubit: quantum computing with chiral anomaly"

    Presented by Dmitri Kharzeev, Stony Brook University and BNL

    12 pm, Building 510, Room 2-160

    Thursday, May 2, 2019, 12:00 pm

    Hosted by: Yuta Kikuchi

    The quantum chiral anomaly enables a nearly dissipationless current in the presence of chirality imbalance and magnetic field – this is the Chiral Magnetic Effect (CME), observed recently in Dirac and Weyl semimetals. We propose to utilize the CME for the design of qubits potentially capable of operating at THz frequency, room temperature, and the coherence time to gate time ratio of about 10^4 . The proposed "Chiral Qubit" is a micron-scale ring made of a Weyl or Dirac semimetal, with the |0> and |1> quantum states corresponding to the symmetric and antisymmetric superpositions of quantum states describing chiral fermions circulating along the ring clockwise and counter-clockwise. A fractional magnetic flux through the ring induces a quantum superposition of the |0> and |1> quantum states. The entanglement of qubits can be implemented through the near-field THz frequency electromagnetic fields.

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