Add to ORKGExciting temporal oscillations of the density distribution is a high-precision method for probing ultracold trapped atomic gases. Interaction effects in their many-body dynamics are particularly puzzling and counter-intuitive in one spatial dimension (1D) due to enhanced quantum correlations. We consider 1D quantum Bose gas in a parabolic trap at zero temperature and explain, analytically and numerically, how oscillation frequency depends on the number of particles, their repulsion, and the trap strength. We identify the frequency with the energy difference between the ground state and a particular excited state. This way we avoided resolving the dynamical evolution of the system, simplifying the problem immensely. We find an excellent quan...
International audienceWe develop a finite-temperature hydrodynamic approach for a harmonically trapp...
Motivated by a recent experiment (Catani J. et al., Phys. Rev. A, 85 (2012) 023623) we study breathi...
We suggest that collective oscillation frequencies of cold trapped gases can be used as high precisi...
Exciting temporal oscillations of the density distribution is a high-precision method for probing ul...
A study of breathing oscillations of a one-dimensional trapped interacting Bose gas is presented. Os...
Ultracold atoms are exceptional tools to explore the physics of quantum matter. In fact, the high de...
We study the breathing (monopole) oscillations and their damping in a harmonically trapped one-dimen...
We study the nonequilibrium dynamics of a one-dimensional Bose gas trapped by a harmonic potential f...
In this thesis we study the physics of quantum many-body systems confined to one-dimensional geometr...
Motivated by current interest in the dynamics of trapped quantum gases, we study the microcanonical ...
We theoretically investigate collective modes of a one-dimensional (1D) interacting Bose gas in a ha...
We study the nonequilibrium dynamics of a one-dimensional Bose gas trapped by a harmonic potential f...
Motivated by current interest in the dynamics of trapped quantum gases, we study the microcanonical ...
Motivated by current interest in the dynamics of trapped quantum gases, we study the microcanonical ...
Motivated by current interest in the dynamics of trapped quantum gases, we study the microcanonical ...
International audienceWe develop a finite-temperature hydrodynamic approach for a harmonically trapp...
Motivated by a recent experiment (Catani J. et al., Phys. Rev. A, 85 (2012) 023623) we study breathi...
We suggest that collective oscillation frequencies of cold trapped gases can be used as high precisi...
Exciting temporal oscillations of the density distribution is a high-precision method for probing ul...
A study of breathing oscillations of a one-dimensional trapped interacting Bose gas is presented. Os...
Ultracold atoms are exceptional tools to explore the physics of quantum matter. In fact, the high de...
We study the breathing (monopole) oscillations and their damping in a harmonically trapped one-dimen...
We study the nonequilibrium dynamics of a one-dimensional Bose gas trapped by a harmonic potential f...
In this thesis we study the physics of quantum many-body systems confined to one-dimensional geometr...
Motivated by current interest in the dynamics of trapped quantum gases, we study the microcanonical ...
We theoretically investigate collective modes of a one-dimensional (1D) interacting Bose gas in a ha...
We study the nonequilibrium dynamics of a one-dimensional Bose gas trapped by a harmonic potential f...
Motivated by current interest in the dynamics of trapped quantum gases, we study the microcanonical ...
Motivated by current interest in the dynamics of trapped quantum gases, we study the microcanonical ...
Motivated by current interest in the dynamics of trapped quantum gases, we study the microcanonical ...
International audienceWe develop a finite-temperature hydrodynamic approach for a harmonically trapp...
Motivated by a recent experiment (Catani J. et al., Phys. Rev. A, 85 (2012) 023623) we study breathi...
We suggest that collective oscillation frequencies of cold trapped gases can be used as high precisi...