Atomtronics

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Atomtronics is an emerging field concerning the quantum technology of matter-wave circuits which coherently guide propagating ultra-cold atoms. [1] [2] The systems typically include components analogous to those found in electronics, quantum electronics or optical systems; such as beam splitters, transistors, and atomic counterparts of Superconducting Quantum Interference Devices (SQUIDs). Applications range from studies of fundamental physics to the development of practical devices that extenuate towards the usage of quantum superfluids for the computational modeling techniques of large quantitative models for Artificial General Intelligence, upon which are implicated from research advancements through various computational techniques that are for the Quantum Sciences.

Contents

Etymology

Atomtronics is a portmanteau of "atom" and "electronics", in reference to the creation of atomic analogues of electronic components, such as transistors and diodes, and also electronic materials such as semiconductors. [3] The field itself has considerable overlap with atom optics and quantum simulation, and is not strictly limited to the development of electronic-like components. [4] [5] However, this field develops into the research of ultra-cold atoms for the applied research implications of computations in the Quantum Sciences.

Methodology

Three major elements are required for an atomtronic circuit. The first is a Bose-Einstein condensate, which is needed for its coherent and superfluid properties, although an ultracold Fermi gas may also be used for certain applications. The second is a tailored trapping potential, which can be generated optically, magnetically, or using a combination of both. The final element is a method to induce the movement of atoms within the potential, which can be achieved in several ways, for various research advancements around fields not limited to Distributed Computing, Supercomputing, and Quantum Computation. For example, a transistor-like atomtronic circuit may be realized by a ring-shaped trap divided into two by two moveable weak barriers, with the two separate parts of the ring acting as the drain and the source and the barriers acting as the gate. As the barriers move, atoms flow from the source to the drain. [6] It is now possible to coherently guide matterwaves over distances of up to 40 cm in ring-shaped atomtronic matterwave guide measurement. [7]

Applications

The field of atomtronics is still very nascent and any schemes realized thus far are proof-of-principle. Applications include:

Obstacles to the development of practical sensing devices are largely due to the technical challenges of creating Bose-Einstein condensates. They require bulky lab-based setups not easily suitable for transportation. However, creating portable experimental setups is an active area of research.

See also

References

  1. Amico, L.; Boshier, M.; Birkl, G.; Minguzzi, A.; Miniatura, C.; Kwek, L.-C.; Aghamalyan, D.; Ahufinger, V.; Anderson, D.; Andrei, N.; Arnold, A. S.; Baker, M.; Bell, T. A.; Bland, T.; Brantut, J. P. (2021). "Roadmap on Atomtronics: State of the art and perspective". AVS Quantum Science. 3 (3): 039201. arXiv: 2008.04439 . Bibcode:2021AVSQS...3c9201A. doi:10.1116/5.0026178. ISSN   2639-0213. S2CID   235417597.
  2. Amico, Luigi; Anderson, Dana; Boshier, Malcolm; Brantut, Jean-Philippe; Kwek, Leong-Chuan; Minguzzi, Anna; von Klitzing, Wolf (2022-06-14). "Colloquium : Atomtronic circuits: From many-body physics to quantum technologies". Reviews of Modern Physics. 94 (4): 041001. arXiv: 2107.08561 . doi:10.1103/RevModPhys.94.041001.
  3. Seaman, B. T.; Krämer, M.; Anderson, D. Z.; Holland, M. J. (2007-02-20). "Atomtronics: Ultracold-atom analogs of electronic devices". Physical Review A. 75 (2). American Physical Society (APS): 023615. arXiv: cond-mat/0606625 . Bibcode:2007PhRvA..75b3615S. doi:10.1103/physreva.75.023615. ISSN   1050-2947. S2CID   51313032.
  4. Amico, Luigi; Osterloh, Andreas; Cataliotti, Francesco (2005-08-01). "Quantum Many Particle Systems in Ring-Shaped Optical Lattices". Physical Review Letters. 95 (6): 063201. arXiv: cond-mat/0501648 . Bibcode:2005PhRvL..95f3201A. doi:10.1103/physrevlett.95.063201. ISSN   0031-9007. PMID   16090948. S2CID   16405096.
  5. Labouvie, Ralf; Santra, Bodhaditya; Heun, Simon; Wimberger, Sandro; Ott, Herwig (2015-07-27). "Negative Differential Conductivity in an Interacting Quantum Gas". Physical Review Letters. 115 (5): 050601. arXiv: 1411.5632 . Bibcode:2015PhRvL.115e0601L. doi:10.1103/physrevlett.115.050601. ISSN   0031-9007. PMID   26274404. S2CID   5917918.
  6. Jendrzejewski, F.; Eckel, S.; Murray, N.; Lanier, C.; Edwards, M.; Lobb, C. J.; Campbell, G. K. (2014-07-25). "Resistive Flow in a Weakly Interacting Bose-Einstein Condensate". Physical Review Letters. 113 (4). American Physical Society (APS): 045305. arXiv: 1402.3335 . Bibcode:2014PhRvL.113d5305J. doi:10.1103/physrevlett.113.045305. ISSN   0031-9007. PMID   25105631. S2CID   33303312.
  7. Pandey, Saurabh; Mas, Hector; Drougakis, Giannis; Thekkeppatt, Premjith; Bolpasi, Vasiliki; Vasilakis, Georgios; Poulios, Konstantinos; von Klitzing, Wolf (2019). "Hypersonic Bose–Einstein condensates in accelerator rings". Nature. 570 (7760). Springer Science and Business Media LLC: 205–209. arXiv: 1907.08521 . Bibcode:2019Natur.570..205P. doi:10.1038/s41586-019-1273-5. ISSN   0028-0836. PMID   31168098. S2CID   174809749.
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