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Juan Ramón Muñoz de Nova (Universidad Complutense de Madrid)18/12/2025, 10:50
Quantum Mechanics is the fundamental theory of the microscopic world, developed at the beginning of the 20th century. The study of quantum foundations and the classical-quantum frontier is still nowadays an active field of research, with direct applications in quantum technologies. However, little attention has been devoted to experimental tests of quantum signatures at relativistic energies,...
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Juan José Gálvez Viruet (Univ. Complutense de Madrid)18/12/2025, 11:40
The real-time phenomenology of QCD remains elusive to traditional computational techniques based on Monte Carlo sampling in Euclidean space. In contrast, on Quantum Computers the time evolution is in principle possible because the basic gates form a universal set of unitary transformations.
In this context, we discuss the calculation of fragmentation functions, key to describe how quarks...
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Youssef KHLIFI (IGFAE_USC)18/12/2025, 12:10
Entanglement offers a compact and quantitative way to characterize correlations in quantum many-body systems, and can therefore provide new information on nuclear structure beyond standard observables. In this talk I discuss how quantum-information concepts—focusing on spin entanglement—can be connected to few-body nuclear dynamics, with emphasis on two-proton emission. Motivated by recent...
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Nahia J. Dios Bilbao18/12/2025, 12:40
The aim of this work is to constrain the neutron star equation of state (EoS). At the energy densities characteristic of neutron star cores, QCD is non-perturbative and the EoS is currently poorly constrained. Classical methods such as Lattice QCD present limitations when dealing with finite density systems. To address this challenge, we use Quantum Computing techniques to simulate the...
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