Your search keyword '"Tilman Esslinger"' showing total 6 results

1. Self-oscillating pump in a topological dissipative atom-cavity system

Author

Davide, Dreon, Alexander, Baumgärtner, Xiangliang, Li, Simon, Hertlein, Tilman, Esslinger, and Tobias, Donner

Abstract

Pumps are transport mechanisms in which direct currents result from a cyclic evolution of the potential

Published

2021

2. Experimental realization of the topological Haldane model with ultracold fermions

Author

Tilman Esslinger, Daniel Greif, Thomas Uehlinger, Gregor Jotzu, Rémi Desbuquois, Michael Messer, and Martin Lebrat

Subjects

Physics, Multidisciplinary, Point reflection, Fermion, Quantum Hall effect, Topology, Symmetry protected topological order, symbols.namesake, Quantum mechanics, Topological insulator, Homogeneous space, symbols, Hamiltonian (quantum mechanics), Electronic band structure

Abstract

The Haldane model on a honeycomb lattice is a paradigmatic example of a Hamiltonian featuring topologically distinct phases of matter. It describes a mechanism through which a quantum Hall effect can appear as an intrinsic property of a band structure, rather than being caused by an external magnetic field. Although physical implementation has been considered unlikely, the Haldane model has provided the conceptual basis for theoretical and experimental research exploring topological insulators and superconductors. Here we report the experimental realization of the Haldane model and the characterization of its topological band structure, using ultracold fermionic atoms in a periodically modulated optical honeycomb lattice. The Haldane model is based on breaking both time-reversal symmetry and inversion symmetry. To break time-reversal symmetry, we introduce complex next-nearest-neighbour tunnelling terms, which we induce through circular modulation of the lattice position. To break inversion symmetry, we create an energy offset between neighbouring sites. Breaking either of these symmetries opens a gap in the band structure, which we probe using momentum-resolved interband transitions. We explore the resulting Berry curvatures, which characterize the topology of the lowest band, by applying a constant force to the atoms and find orthogonal drifts analogous to a Hall current. The competition between the two broken symmetries gives rise to a transition between topologically distinct regimes. By identifying the vanishing gap at a single Dirac point, we map out this transition line experimentally and quantitatively compare it to calculations using Floquet theory without free parameters. We verify that our approach, which allows us to tune the topological properties dynamically, is suitable even for interacting fermionic systems. Furthermore, we propose a direct extension to realize spin-dependent topological Hamiltonians.

Published

2014

3. Cavity QED with a Bose–Einstein condensate

Author

Tobias Donner, Michael Köhl, Stephan Ritter, Ferdinand Brennecke, Tilman Esslinger, and Thomas Bourdel

Subjects

Condensed Matter::Quantum Gases, Physics, Quantum Physics, Multidisciplinary, Photon, Cavity quantum electrodynamics, FOS: Physical sciences, Physics::Optics, law.invention, Condensed Matter - Other Condensed Matter, Open quantum system, law, Quantum state, Quantum electrodynamics, Optical cavity, Quantum mechanics, Physics::Atomic Physics, Quantum information, Quantum Physics (quant-ph), Quantum information science, Bose–Einstein condensate, Other Condensed Matter (cond-mat.other)

Abstract

Cavity quantum electrodynamics (cavity QED) describes the coherent interaction between matter and an electromagnetic field confined within a resonator structure, and is providing a useful platform for developing concepts in quantum information processing. By using high-quality resonators, a strong coupling regime can be reached experimentally in which atoms coherently exchange a photon with a single light-field mode many times before dissipation sets in. This has led to fundamental studies with both microwave and optical resonators. To meet the challenges posed by quantum state engineering and quantum information processing, recent experiments have focused on laser cooling and trapping of atoms inside an optical cavity. However, the tremendous degree of control over atomic gases achieved with Bose-Einstein condensation has so far not been used for cavity QED. Here we achieve the strong coupling of a Bose-Einstein condensate to the quantized field of an ultrahigh-finesse optical cavity and present a measurement of its eigenenergy spectrum. This is a conceptually new regime of cavity QED, in which all atoms occupy a single mode of a matter-wave field and couple identically to the light field, sharing a single excitation. This opens possibilities ranging from quantum communication to a wealth of new phenomena that can be expected in the many-body physics of quantum gases with cavity-mediated interactions., 6 pages, 4 figures; version accepted for publication in Nature; updated Fig. 4; changed atom numbers due to new calibration

Published

2007

4. Quantum phase transition from a superfluid to a Mott insulator in a gas of ultracold atoms

Author

Markus Greiner, Tilman Esslinger, Theodor W. Hänsch, Olaf Mandel, and Immanuel Bloch

Subjects

Condensed Matter::Quantum Gases, Physics, Quantum phase transition, Optical lattice, Phase transition, Multidisciplinary, Condensed matter physics, Quantum critical point, Quantum phases, Superfluid film, Jaynes–Cummings–Hubbard model, Mott transition

Abstract

For a system at a temperature of absolute zero, all thermal fluctuations are frozen out, while quantum fluctuations prevail. These microscopic quantum fluctuations can induce a macroscopic phase transition in the ground state of a many-body system when the relative strength of two competing energy terms is varied across a critical value. Here we observe such a quantum phase transition in a Bose-Einstein condensate with repulsive interactions, held in a three-dimensional optical lattice potential. As the potential depth of the lattice is increased, a transition is observed from a superfluid to a Mott insulator phase. In the superfluid phase, each atom is spread out over the entire lattice, with long-range phase coherence. But in the insulating phase, exact numbers of atoms are localized at individual lattice sites, with no phase coherence across the lattice; this phase is characterized by a gap in the excitation spectrum. We can induce reversible changes between the two ground states of the system.

Published

2002

5. Measurement of the spatial coherence of a trapped Bose gas at the phase transition

Author

Tilman Esslinger, Theodor W. Hänsch, and Immanuel Bloch

Subjects

Condensed Matter::Quantum Gases, Physics, Phase transition, Multidisciplinary, Bose gas, Condensed matter physics, Macroscopic quantum phenomena, Degree of coherence, Molecular physics, law.invention, Superfluidity, law, Matter wave, Bose–Einstein condensate, Coherence (physics)

Abstract

The experimental realization of Bose–Einstein condensates of dilute gases1,2,3 has allowed investigations of fundamental concepts in quantum mechanics at ultra-low temperatures, such as wave-like behaviour and interference phenomena. The formation of an interference pattern depends fundamentally on the phase coherence of a system; the latter may be quantified by the spatial correlation function. Phase coherence over a long range4,5,6,7 is the essential factor underlying Bose–Einstein condensation and related macroscopic quantum phenomena, such as superconductivity and superfluidity. Here we report a direct measurement of the phase coherence properties of a weakly interacting Bose gas of rubidium atoms. Effectively, we create a double slit for magnetically trapped atoms using a radio wave field with two frequency components. The correlation function of the system is determined by evaluating the interference pattern of two matter waves originating from the spatially separated ‘slit’ regions of the trapped gas. Above the critical temperature for Bose–Einstein condensation, the correlation function shows a rapid gaussian decay, as expected for a thermal gas. Below the critical temperature, the correlation function has a different shape: a slow decay towards a plateau is observed, indicating the long-range phase coherence of the condensate fraction.

Published

2000

6. Atomic gas in flatland

Author

Gianni Blatter and Tilman Esslinger

Subjects

Condensed Matter::Quantum Gases, Physics, Phase transition, Multidisciplinary, Condensed matter physics, Condensed Matter::Other, Condensation, chemistry.chemical_element, Thermal fluctuations, Vortex, Rubidium, Superfluidity, chemistry, Ferromagnetism, Pairing, Quantum mechanics

Abstract

The observation of Bose–Einstein condensation in an atomic gas was a seminal result. Two-dimensional gases are more complex, and an intriguing interference experiment has exposed a different superfluid transition. Physics in a two-dimensional environment is very different from what we observe in the three-dimensional world. If dimensionality is reduced, thermal fluctuations destroy a system's spatial order and most phase transitions, like those responsible for ferromagnetism for instance, cannot occur. But there is a particular type of phase transition, involving the pairing of vortices, that does exist in two dimensions. First predicted 30 years ago by Berezinskii, Kosterlitz and Thouless, the ‘BKT transition’ has now been observed directly for the first time in a planar gas of ultracold rubidium atoms.

Published

2006