Dr. Mikhail Bashkanov DEPARTMENT of PHYSICS COLLOQUIUM

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Dr. Mikhail Bashkanov DEPARTMENT of PHYSICS COLLOQUIUM DEPARTMENT OF PHYSICS COLLOQUIUM Secret Life of Exotic Hadrons: from Lightest Systems to Neutron Stars Dr. Mikhail Bashkanov Edinburgh University Several new findings in the four, five and six quark systems reheat the interest in the field of multiquark states (beyond trivial �"� and ���). A lot of progress has recently been made in the 6� sector, on both the theoretical and experimental side. The d*(2380) hexaquark is the only multiquark state which can be produced copiously at current facilities, offering unique access to information beyond its basic quantum numbers, particularly its physical size, magnetic moment, quadrupole deformation and internal structure. Latest experiments on d* photoproduction provide new information on multiquark system dynamics. Neutron stars are other valuable laboratories to study the fundamental properties of dense nuclear/quark matter. Neutron star mergers, such as recently observed by LIGO with both electromagnetic and gravitational wave signals, have properties which depend strongly on the Equation of State. A number of exotic possibilities have been investigated as possible degrees of freedom within neutron stars. It was recently demonstrated that hexaquarks have the potential for major impact on the properties of the dense nuclear matter in neutron stars and during neutron star mergers. It will be shown that the properties of this nucleonic matter can be constrained by precision measurements of nuclei and nuclear reactions at ground based experiments. TIME:TIME: 3:454:00--4:455:00 pm,pm, Thursday, Thursday, FebruaryFebruary 22,1, 2018 2018 (refreshments: 3:303:45 pm in the hallway) PLACE: Bennhold Auditorium (room 101), Corcoran Hall, GWU 725 21st Street, NW, Washington, DC 20052 METRO STATION: GWU/FOGGY BOTTOM (BLUE, ORANGE & SILVER LINES).
Recommended publications
  • (2380) in a Hexaquark Scenario
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  • Diffractive Dissociation of Alpha Particles As a Test of Isophobic Short-Range Correlations Inside Nuclei ∗ Jennifer Rittenhouse West A, , Stanley J
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  • A New Possibility for Light-Quark Dark Matter 2
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