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Our Areas of Research

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 Colleen Michael, 1-631-344-4919.


RBRC Research Groups

McLerran
Theory

L. McLerran, 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.

Izubuchi
Computing

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.

Akiba
Experimental

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. MAY

    1

    Friday

    Nuclear Theory/RIKEN Seminar

    "Applications of Soft-Collinear Effective theory to hadronic and nuclear collisions"

    Presented by Ivan Vitev, Los Alamos National Laboratory

    2 pm, Small Seminar Room, Bldg. 510

    Friday, May 1, 2015, 2:00 pm

    Hosted by: Soeren Schlichting

    Effective field theory (EFT) is a powerful framework based on exploiting symmetries and controlled expansions for problems with a natural separation of energy or distance scales. EFTs are particularly important in QCD and nuclear physics. An effective theory of QCD, ideally suited to jet applications, is Soft-Collinear Effective Theory (SCET). Recently, first steps were taken to extend SCET and describe jet evolution in strongly-interacting matter. In this talk I will demonstrate that the newly constructed theory, called SCETG, allows us to go beyond the traditional energy loss approximation in heavy ion collisions and unify the treatment of vacuum and medium-induced parton showers. It provides quantitative control over the uncertainties associated with the implementation of the in-medim modification of hadron production cross sections and allows us to accurately constrain the coupling between the jet and the medium. I will further show how SCET and SCETG can be implemented to evaluate reconstructed jet observables, such as jet shapes.

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