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Nanoparticle interferometer by throw and catch

Nanoparticle interferometer by throw and catch
Nanoparticle interferometer by throw and catch
Matter wave interferometry with increasingly larger masses could pave the way to understanding the nature of wavefunction collapse, the quantum to classical transition, or even how an object in a spatial superposition interacts with its gravitational field. In order to improve upon the current mass record, it is necessary to move into the nanoparticle regime. In this paper, we provide a design for a nanoparticle Talbot–Lau matter wave interferometer that circumvents the practical challenges of previously proposed designs. We present numerical estimates of the expected fringe patterns that such an interferometer would produce, considering all major sources of decoherence. We discuss the practical challenges involved in building such an experiment, as well as some preliminary experimental results to illustrate the proposed measurement scheme. We show that such a design is suitable for seeing interference fringes with 106 amu SiO2 particles and that this design can be extended to even 108 amu particles by using flight times below the typical Talbot time of the system.
2218-2004
Wardak, Jakub
7df868f6-b11a-482a-a2db-b777871655d8
Georgescu, Tiberius
90e287ef-1bc3-43a1-8cb7-38a47c440e07
Gasbarri, Giulio
a219ce12-3f3f-4b63-a83d-edf343fac3cc
Belenchia, Alessio
3a8337e5-8f17-4db7-8c0b-f731910dca3c
Ulbricht, Hendrik
5060dd43-2dc1-47f8-9339-c1a26719527d
Wardak, Jakub
7df868f6-b11a-482a-a2db-b777871655d8
Georgescu, Tiberius
90e287ef-1bc3-43a1-8cb7-38a47c440e07
Gasbarri, Giulio
a219ce12-3f3f-4b63-a83d-edf343fac3cc
Belenchia, Alessio
3a8337e5-8f17-4db7-8c0b-f731910dca3c
Ulbricht, Hendrik
5060dd43-2dc1-47f8-9339-c1a26719527d

Wardak, Jakub, Georgescu, Tiberius, Gasbarri, Giulio, Belenchia, Alessio and Ulbricht, Hendrik (2024) Nanoparticle interferometer by throw and catch. Atoms, 12 (2), [7]. (doi:10.3390/atoms12020007).

Record type: Article

Abstract

Matter wave interferometry with increasingly larger masses could pave the way to understanding the nature of wavefunction collapse, the quantum to classical transition, or even how an object in a spatial superposition interacts with its gravitational field. In order to improve upon the current mass record, it is necessary to move into the nanoparticle regime. In this paper, we provide a design for a nanoparticle Talbot–Lau matter wave interferometer that circumvents the practical challenges of previously proposed designs. We present numerical estimates of the expected fringe patterns that such an interferometer would produce, considering all major sources of decoherence. We discuss the practical challenges involved in building such an experiment, as well as some preliminary experimental results to illustrate the proposed measurement scheme. We show that such a design is suitable for seeing interference fringes with 106 amu SiO2 particles and that this design can be extended to even 108 amu particles by using flight times below the typical Talbot time of the system.

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Accepted/In Press date: 19 January 2024
Published date: 25 January 2024
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Identifiers

Local EPrints ID: 497737
URI: http://eprints.soton.ac.uk/id/eprint/497737
DOI: doi:10.3390/atoms12020007
ISSN: 2218-2004
PURE UUID: 16f08937-c90b-430a-adfd-96cfbaa3edf8
ORCID for Hendrik Ulbricht: ORCID iD orcid.org/0000-0003-0356-0065

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Date deposited: 30 Jan 2025 17:44
Last modified: 22 Aug 2025 01:59

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Contributors

Author: Jakub Wardak
Author: Tiberius Georgescu
Author: Giulio Gasbarri
Author: Alessio Belenchia
Author: Hendrik Ulbricht ORCID iD

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