Quantum Rings in the Hold of Laser Light: Ultracold Atoms Trapped in Surprisingly Complex Structures

Quantum Rings Laser Light

Ultracold atoms caught in an optical trap form suprisingly complex structures. Depending on mutual interactions between particles with opposite spins, phases with various properties can be created locally. Credit: IFJ PAN

Ultracold atoms trapped in appropriately prepared optical traps can arrange themselves in surprisingly complex, hitherto unobserved structures, according to scientists from the Institute of Nuclear Physics of the Polish Academy of Sciences in Cracow. In line with their most recent predictions, matter in optical lattices should form tensile and inhomogeneous quantum rings in a controlled manner.

An optical lattice is a structure built of light, i.e. electromagnetic waves. Lasers play a key role in the construction of such lattices. Each laser generates an electromagnetic wave with strictly defined, constant parameters which can be almost arbitrarily modified. When the laser beams are matched properly, it is possible to create a lattice with well known properties. By overlapping of waves, the minima of potential can be obtained, whose arrangement enables simulation of the systems and models well-known from solid states physics. The advantage of such prepared systems is the relatively simple way to modify the positions of these minima, which in practice means the possibility of preparing various type of lattices.

“If we introduce appropriately selected atoms into an area of space that has been prepared in this way, they will congregate in the locations of potential minima. However, there is an important condition: the atoms must be cooled to ultra-low temperatures. Only then will their energy be small enough not to break out of the subtle prepared trap,” explains Dr. Andrzej Ptok from the Institute of Nuclear Physics of the Polish Academy of Sciences (IFJ PAN) in Cracow.

Structures formed by atoms (or groups of atoms) trapped in the optical lattice resemble crystals. Depending on the configuration of the laser beams, they can be one-, two- or three-dimensional. Unlike crystals, they are defect-free. What’s more, while in crystals the possibility of modifying the structure of the lattice is negligible, optical lattices are quite easy to configure. All that’s needed is to change the properties of the laser light or the cutting angles of the beams. These features make optical lattices popular as quantum simulators. They can be used to reproduce various spatial configurations of atoms or groups of atoms, including even those that do not exist in nature.

In their research, the scientists from the IFJ PAN work with trapped atoms in optical lattices. Groups of fermions, i.e. atoms with spin of 1/2 (spin is a quantum feature describing the rotation of particles) were placed in their sites. In each site a certain number of atoms had the spin oriented in one direction (up), and the rest – in the opposite direction (down). Modification of interaction between atoms in such a way to be attractive leads to the creation of pairs of atoms, which correspond to the Cooper pairs in superconductors – pairs of electrons with opposite spins in the same site of lattice.

“The parameters of the optical lattice can be used to influence the interaction between atoms of different spin trapped in individual sites. Moreover, in such way a state can be prepared, which mimic the applied external magnetic fields on the system. It is given by controlling the proportions between the numbers of atoms of different spin,” says Dr. Konrad J. Kapcia from IFJ PAN and notes that systems prepared in this way can reproduce the effects of relatively large magnetic fields without needing to use these fields. “This is possible because we know how a given magnetic field would impact into the difference between numbers of particles with opposite spins,” explains researchers.

According to the predictions of the Cracow-based physicists, an interesting phase separation should take place in systems prepared in this manner. As a result, core-shell structure formed by matter trapped in an optical lattice, a core of paired atoms of one phase, surrounded by a shell of paired atoms of the second phase, will automatically form.

“The whole situation can be represented by a tasty example. Imagine a plate of rice with a thick sauce. By proper preparation of the plate, we can affect the relative position between the rice and the sauce. For example, we can prepare the system in such a way, that the rice will be in the center, while the sauce forms a ring around it. From the same ingredients we can also construct the reverse system: in the middle of the plate there will be the sauce surrounded by a ring of rice. In our case, the plate is the optical trap with atoms and their pairs, and the rice and sauce are the two phases, grouping different types of atom pairs”, Dr. Ptok describes.

The work of the physicists from IFJ PAN, published in Scientific Reports, is of a theoretical nature. Due to their simplicity, however, the described systems of ultracold atoms in optical traps can be quickly verified in laboratory experiments. Physicists from the IFJ PAN predicted that ultracold atoms trapped in optical lattices can form quantum rings with an inhomogeneous structure.

References:

“Superfluidity of fermionic pairs in a harmonic trap. Comparative studies: Local Density Approximation and Bogoliubov-de Gennes solutions” by Agnieszka Cichy and Andrzej Ptok, 14 May 2020, Journal of Physics Communications.
DOI: 10.1088/2399-6528/ab8f02

“Phase separations induced by a trapping potential in one-dimensional fermionic systems as a source of core-shell structures” by Agnieszka Cichy, Konrad Jerzy Kapcia and Andrzej Ptok, 30 April 2019, Scientific Reports.
DOI: 10.1038/s41598-019-42044-w

The Henryk Niewodniczanski Institute of Nuclear Physics (IFJ PAN) is currently the largest research institute of the Polish Academy of Sciences. The broad range of studies and activities of IFJ PAN includes basic and applied research, ranging from particle physics and astrophysics, through hadron physics, high-, medium-, and low-energy nuclear physics, condensed matter physics (including materials engineering), to various applications of methods of nuclear physics in interdisciplinary research, covering medical physics, dosimetry, radiation and environmental biology, environmental protection, and other related disciplines. The average yearly yield of the IFJ PAN encompasses more than 600 scientific papers in the Journal Citation Reports published by the Clarivate Analytics. The part of the Institute is the Cyclotron Centre Bronowice (CCB) which is an infrastructure, unique in Central Europe, to serve as a clinical and research centre in the area of medical and nuclear physics. IFJ PAN is a member of the Marian Smoluchowski Kraków Research Consortium: “Matter-Energy-Future” which possesses the status of a Leading National Research Centre (KNOW) in physics for the years 2012-2017. In 2017 the European Commission granted to the Institute the HR Excellence in Research award. The Institute is of A+ Category (leading level in Poland) in the field of sciences and engineering.

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