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Properties of Z_c(3900) tetraquark in a cold nuclear matter

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arxiv 2001.09356 v3 pith:WP3ROS5J submitted 2020-01-25 hep-ph hep-exhep-lat

Properties of Z_c(3900) tetraquark in a cold nuclear matter

classification hep-ph hep-exhep-lat
keywords densitymatterstatemassmediumnuclearpropertiesbehavior
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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The study of medium effects on properties of particles embedded in nuclear matter is of great importance for understanding the nature and internal quark-gluon organization as well as exact determination of the quantum numbers, especially of the exotic states. In this context, we study the physical properties of one of the famous charmonium-like states, $Z_c(3900)$, in a cold dense matter. We investigate the possible shifts in the mass and current-meson coupling of the $Z_c(3900)$ state due to the dense medium at saturation density, $ \rho^{sat} $, by means of the in-medium sum rules. We also estimate the vector self-energy of this state at saturation nuclear matter density. We discuss the behavior of the spectroscopic parameters of this state with respect to the density up to a high density corresponding to the core of neutron stars, $\rho\approx 5\rho^{sat}$. Both the mass and current-coupling of this state show nonlinear behavior and decrease with respect to the density of the medium: the mass reaches roughly $30\%$ of its vacuum value at $ \rho=5\rho^{sat} $, while the current-coupling approaches zero at $ \rho\approx2.1\rho^{sat} $, when the central values of the auxiliary and other input parameters are used.

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