Theodor W. Hänsch scite author profile

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.

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Tonks–Girardeau gas of ultracold atoms in an optical lattice

Paredes¹,

Widera²,

Murg³

et al. 2004

Nature

1,551

2,001

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Strongly correlated quantum systems are among the most intriguing and fundamental systems in physics. One such example is the Tonks-Girardeau gas, proposed about 40 years ago, but until now lacking experimental realization; in such a gas, the repulsive interactions between bosonic particles confined to one dimension dominate the physics of the system. In order to minimize their mutual repulsion, the bosons are prevented from occupying the same position in space. This mimics the Pauli exclusion principle for fermions, causing the bosonic particles to exhibit fermionic properties. However, such bosons do not exhibit completely ideal fermionic (or bosonic) quantum behaviour; for example, this is reflected in their characteristic momentum distribution. Here we report the preparation of a Tonks-Girardeau gas of ultracold rubidium atoms held in a two-dimensional optical lattice formed by two orthogonal standing waves. The addition of a third, shallower lattice potential along the long axis of the quantum gases allows us to enter the Tonks-Girardeau regime by increasing the atoms' effective mass and thereby enhancing the role of interactions. We make a theoretical prediction of the momentum distribution based on an approach in which trapped bosons acquire fermionic properties, finding that it agrees closely with the measured distribution.

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Collapse and revival of the matter wave field of a Bose–Einstein condensate

Greiner

Mandel

Hänsch

et al. 2002

Nature

1,204

1,485

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While the matter wave field of a Bose-Einstein condensate is usually assumed to be intrinsically stable, apart from incoherent loss processes, it has been pointed out that this should not be true when a Bose-Einstein condensate is in a coherent superposition of different atom number states [1][2][3][4][5][6] . This is the case for example whenever a Bose-Einstein condensate is split into two parts, such that a well-defined relative phase between the two matter wave fields is established. When these two condensates are isolated from each other, a fundamental question arises: How does the relative phase between the two condensates evolve and what happens to the individual matter wave fields? In this work, we show that in such a case the matter wave field of a Bose-Einstein condensate undergoes a periodic series of collapses and revivals due to the quantized structure of the matter wave field and the collisions between individual atoms.

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