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Properties and similarities of Fermions in nuclear physics, cold atoms and neutron stars
Properties and similarities of Fermions in nuclear physics, cold atoms
and neutron stars
Lectio Magistralis
Lectio Magistralis
Stefano Gandolfi
Stefano Gandolfi
+ Lectio Magistralis
Lectio Magistralis
Stefano Gandolfi
+ Lectio Magistralis
Stefano Gandolfi
' (2004-2007: PhD in Trento)
(2004-2007: PhD in Trento)
Staff member of the theoretical division @ LANL (Los Alamos National Laboratory)
'' (2004-2007: PhD in Trento) ''
Staff member of the theoretical division @ LANL (Los Alamos National Laboratory)
' (2004-2007: PhD in Trento)
Staff member of the theoretical division @ LANL (Los Alamos National Laboratory)
(2004-2007 PhD in Trento)
Staff member of the theoretical division @ LANL (Los Alamos National Laboratory)
'' (2004-2007: PhD in Trento) ''
(2004-2007 PhD in Trento)
(2004-2007 PhD in Trento)
(PhD in Trento)
(2004-2007 PhD in Trento)
Stefano Gandolfi
Stefano Gandolfi
Stefano Gandolfi
Stefano Gandolfi
On the other side, low-density neutron matter exhibits important similarities to properties of strongly interacting Fermi gases that offer the feature to be very manageable in experiments. The unitarity Fermi gas is become the best tool to test the accuracy of many-body techniques that are employed in nuclear physics.\\
On the other side, low-density neutron matter exhibits important similarities to properties of strongly interacting Fermi gases that offer the feature to be very manageable in experiments. The unitary Fermi gas is become the best tool to test the accuracy of many-body techniques that are employed in nuclear physics.\\
''Quantum Monte Carlo methods provide an important tool to predict properties of strongly correlated systems that cannot be studied using perturbation theory. The equation of state of nuclear matter at nuclear densities is the bridge between the terrestrial experiments aiming to measure the symmetry energy and the structure of neutron stars. An even more important challenge is the study of properties of inhomogeneous neutron matter at moderate densities that is not reliable in experiments but is essential to constrain the nuclear density functionals commonly used in the physics of heavy nuclei and to study the crust of neutron stars. \\ On the other side, low-density neutron matter exhibits important similarities to properties of strongly interacting Fermi gases that offer the feature to be very manageable in experiments. The unitary Fermi gas is become the best tool to test the accuracy of many-body techniques that are employed in nuclear physics. In this talk I will present the recent progresses that has been made in these different fields in the last few years.''
''Quantum Monte Carlo methods provide an important tool to predict properties of strongly correlated systems that cannot be studied using perturbation theory. The equation of state of nuclear matter at nuclear densities is the bridge between the terrestrial experiments aiming to measure the symmetry energy and the structure of neutron stars. An even more important challenge is the study of properties of inhomogeneous neutron matter at moderate densities that is not reliable in experiments but is essential to constrain the nuclear density functionals commonly used in the physics of heavy nuclei and to study the crust of neutron stars. On the other side, low-density neutron matter exhibits important similarities to properties of strongly interacting Fermi gases that offer the feature to be very manageable in experiments. The unitarity Fermi gas is become the best tool to test the accuracy of many-body techniques that are employed in nuclear physics.
''Quantum Monte Carlo methods provide an important tool to predict properties of strongly correlated systems that cannot be studied using perturbation theory. The equation of state of nuclear matter at nuclear densities is the bridge between the terrestrial experiments aiming to measure the symmetry energy and the structure of neutron stars. An even more important challenge is the study of properties of inhomogeneous neutron matter at moderate densities that is not reliable in experiments but is essential to constrain the nuclear density functionals commonly used in the physics of heavy nuclei and to study the crust of neutron stars.
On the other side, low-density neutron matter exhibits important similarities to properties of strongly interacting Fermi gases that offer the feature to be very manageable in experiments. The unitarity Fermi gas is become the best tool to test the accuracy of many-body techniques that are employed in nuclear physics.\\
Quantum Monte Carlo methods provide an important tool to predict properties of strongly correlated systems that cannot be studied using perturbation theory. The equation of state of nuclear matter at nuclear densities is the bridge between the terrestrial experiments aiming to measure the symmetry energy and the structure of neutron stars. An even more important challenge is the study of properties of inhomogeneous neutron matter at moderate densities that is not reliable in experiments but is essential to constrain the nuclear density functionals commonly used in the physics of heavy nuclei and to study the crust of neutron stars.
''Quantum Monte Carlo methods provide an important tool to predict properties of strongly correlated systems that cannot be studied using perturbation theory. The equation of state of nuclear matter at nuclear densities is the bridge between the terrestrial experiments aiming to measure the symmetry energy and the structure of neutron stars. An even more important challenge is the study of properties of inhomogeneous neutron matter at moderate densities that is not reliable in experiments but is essential to constrain the nuclear density functionals commonly used in the physics of heavy nuclei and to study the crust of neutron stars. On the other side, low-density neutron matter exhibits important similarities to properties of strongly interacting Fermi gases that offer the feature to be very manageable in experiments. The unitarity Fermi gas is become the best tool to test the accuracy of many-body techniques that are employed in nuclear physics. In this talk I will present the recent progresses that has been made in these different fields in the last web years.''
Quantum Monte Carlo
Quantum Monte Carlo methods provide an important tool to predict properties of strongly correlated systems that cannot be studied using perturbation theory. The equation of state of nuclear matter at nuclear densities is the bridge between the terrestrial experiments aiming to measure the symmetry energy and the structure of neutron stars. An even more important challenge is the study of properties of inhomogeneous neutron matter at moderate densities that is not reliable in experiments but is essential to constrain the nuclear density functionals commonly used in the physics of heavy nuclei and to study the crust of neutron stars.
''Quantum Monte Carlo methods provide an important tool to predict properties of strongly correlated systems that cannot be studied using perturbation theory. The equation of state of nuclear matter at nuclear densities is the bridge between the terrestrial experiments aiming to measure the symmetry energy and the structure of neutron stars. An even more important challenge is the study of properties of inhomogeneous neutron matter at moderate densities that is not reliable in experiments but is essential to constrain the nuclear density functionals commonly used in the physics of heavy nuclei and to study the crust of neutron stars.''
Quantum Monte Carlo
Quantum Monte Carlo
''Quantum Monte Carlo methods provide an important tool to predict properties of strongly correlated systems that cannot be studied using perturbation theory. The equation of state of nuclear matter at nuclear densities is the bridge between the terrestrial experiments aiming to measure the symmetry energy and the structure of neutron stars. An even more important challenge is the study of properties of inhomogeneous neutron matter at moderate densities that is not reliable in experiments but is essential to constrain the nuclear density functionals commonly used in the physics of heavy nuclei and to study the crust of neutron stars.''
Quantum Monte Carlo
stars. On the other side, low-density neutron matter exhibits important
stars. \\ On the other side, low-density neutron matter exhibits important
staff member of the theoretical division @ LANL (Los Alamos National Laboratory)\\
Staff member of the theoretical division @ LANL (Los Alamos National Laboratory)\\
staff member of the theoretical division @LANL (Los Alamos National Laboratory)\\
staff member of the theoretical division @ LANL (Los Alamos National Laboratory)\\
\\
staff member of the theoretical division @LANL (Los Alamos National Laboratory)\\
stars. On the other side, low-density neutron matter exhibits important
stars. On the other side, low-density neutron matter exhibits important
Quantum Monte Carlo methods provide an important tool to predict
''Quantum Monte Carlo methods provide an important tool to predict
these different fields in the last few years.
these different fields in the last few years.''
''Quantum Monte Carlo methods provide an important tool to predict
Quantum Monte Carlo methods provide an important tool to predict
these different fields in the last few years.''
these different fields in the last few years.
Properties and similarities of Fermions in nuclear physics, cold atoms
and neutron stars
Properties and similarities of Fermions in nuclear physics, cold atoms and neutron stars
Properties and similarities of Fermions in nuclear physics, cold atoms
and neutron stars
''Quantum Monte Carlo methods provide an important tool to predict properties of strongly correlated systems that cannot be studied using perturbation theory. The equation of state of nuclear matter at nuclear densities is the bridge between the terrestrial experiments aiming to measure the symmetry energy and the structure of neutron stars. An even more important challenge is the study of properties of inhomogeneous neutron matter at moderate densities that is not reliable in experiments but is essential to constrain the nuclear density functionals commonly used in the physics of heavy nuclei and to study the crust of neutron stars. On the other side, low-density neutron matter exhibits important similarities to properties of strongly interacting Fermi gases that offer the feature to be very manageable in experiments. The unitary Fermi gas is become the best tool to test the accuracy of many-body techniques that are employed in nuclear physics. In this talk I will present the recent progresses that has been made in these different fields in the last few years.''
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