Add to ORKGABSTRACT: “Bottom-up ” approaches to the many-body physics of fermions have recently demonstrated precise number and site-resolved preparations with tunability of interparticle interactions in single-well, SW, and double-well, DW, nanoscale confinements created by manipulating ultracold fermionic atoms with optical tweezers. These experiments emulate an analogue-simulator mapping onto the requisite microscopic Hamiltonian, approaching realization of Feynmans ’ vision of quantum simulators that “will do exactly the same as nature”. Here we report on exact benchmark configuration−interaction computational microscopy solutions of the Hamiltonian, uncovering the spectral evolution, wave function anatomy, and entanglement properties of the inter...
Rapid progress in the field of ultracold atoms allows the study of many new and old models of quantu...
Thesis: Ph. D., Massachusetts Institute of Technology, Department of Physics, 2018.Cataloged from PD...
Many interesting physical systems have one thing in common. Their complexity makes it impossible to ...
“Bottom-up” approaches to the many-body physics of fermions have recently demonstrated precise numbe...
In this thesis, I present and discuss correlation measurements of fermionic quantum systems engineer...
Optical lattices make it possible to trap and coherently control large ensembles of ultracold atoms....
We discuss the experimental engineering of model systems for the description of quantum electrodynam...
Thesis: Ph. D., Massachusetts Institute of Technology, Department of Physics, 2017.Cataloged from PD...
I present experiments with ultracold atoms which demonstrate a novel avenue to study strongly correl...
Seminar Goethe University, Frankfurt, Germany, 18-04-2013Ultracold atomic gases in optical lattices ...
The formation of bound states of fermions in one dimension has always been one of the key topics in ...
CoQuS II Kick-Off Workshop, also honouring Reinhold Bertlmann's 65th Birthday Mitschnitt einer Vera...
International audienceUltracold atomic gases provide a fantastic platform to implement quantum simul...
In this thesis we investigate strongly-correlated states of ultracold bosonic atoms in rotating ring...
The emergence of collective and universal behaviour is at the heart of many of the exotic phases of ...
Rapid progress in the field of ultracold atoms allows the study of many new and old models of quantu...
Thesis: Ph. D., Massachusetts Institute of Technology, Department of Physics, 2018.Cataloged from PD...
Many interesting physical systems have one thing in common. Their complexity makes it impossible to ...
“Bottom-up” approaches to the many-body physics of fermions have recently demonstrated precise numbe...
In this thesis, I present and discuss correlation measurements of fermionic quantum systems engineer...
Optical lattices make it possible to trap and coherently control large ensembles of ultracold atoms....
We discuss the experimental engineering of model systems for the description of quantum electrodynam...
Thesis: Ph. D., Massachusetts Institute of Technology, Department of Physics, 2017.Cataloged from PD...
I present experiments with ultracold atoms which demonstrate a novel avenue to study strongly correl...
Seminar Goethe University, Frankfurt, Germany, 18-04-2013Ultracold atomic gases in optical lattices ...
The formation of bound states of fermions in one dimension has always been one of the key topics in ...
CoQuS II Kick-Off Workshop, also honouring Reinhold Bertlmann's 65th Birthday Mitschnitt einer Vera...
International audienceUltracold atomic gases provide a fantastic platform to implement quantum simul...
In this thesis we investigate strongly-correlated states of ultracold bosonic atoms in rotating ring...
The emergence of collective and universal behaviour is at the heart of many of the exotic phases of ...
Rapid progress in the field of ultracold atoms allows the study of many new and old models of quantu...
Thesis: Ph. D., Massachusetts Institute of Technology, Department of Physics, 2018.Cataloged from PD...
Many interesting physical systems have one thing in common. Their complexity makes it impossible to ...