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Main Authors: Pedalino, Sebastian, Ramírez-Galindo, Bruno E., Ferstl, Richard, Hornberger, Klaus, Arndt, Markus, Gerlich, Stefan
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2507.21211
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author Pedalino, Sebastian
Ramírez-Galindo, Bruno E.
Ferstl, Richard
Hornberger, Klaus
Arndt, Markus
Gerlich, Stefan
author_facet Pedalino, Sebastian
Ramírez-Galindo, Bruno E.
Ferstl, Richard
Hornberger, Klaus
Arndt, Markus
Gerlich, Stefan
contents The quantum superposition principle is a cornerstone of physics and at the heart of many quantum technologies. Yet, it is still often regarded counterintuitive because we do not observe its key features on the macroscopic scales of our daily lives. It is therefore intriguing to ask how quantum properties persist or change as we increase the size and complexity of objects. A paradigmatic test for this question can be realized by matter-wave interferometry, where the motion of individual massive particles becomes delocalized and needs to be described by a wave function that spans regions far larger than the particle itself. Here we present an experimental platform extending matter-wave interference to a qualitatively new class of materials that can vary widely in mass and size. We specifically demonstrate quantum interference of sodium nanoparticles, which can each contain more than 7'000 atoms at masses greater than 170'000 dalton. They propagate in a Schrödinger cat state with a macroscopicity of $μ$ = 15.5, surpassing all previous experiments by an order of magnitude and providing the most stringent exclusion limit for generic macrorealistic modifications of the Schrödinger equation to date.
format Preprint
id arxiv_https___arxiv_org_abs_2507_21211
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Probing quantum mechanics using nanoparticle Schrödinger cats
Pedalino, Sebastian
Ramírez-Galindo, Bruno E.
Ferstl, Richard
Hornberger, Klaus
Arndt, Markus
Gerlich, Stefan
Quantum Physics
The quantum superposition principle is a cornerstone of physics and at the heart of many quantum technologies. Yet, it is still often regarded counterintuitive because we do not observe its key features on the macroscopic scales of our daily lives. It is therefore intriguing to ask how quantum properties persist or change as we increase the size and complexity of objects. A paradigmatic test for this question can be realized by matter-wave interferometry, where the motion of individual massive particles becomes delocalized and needs to be described by a wave function that spans regions far larger than the particle itself. Here we present an experimental platform extending matter-wave interference to a qualitatively new class of materials that can vary widely in mass and size. We specifically demonstrate quantum interference of sodium nanoparticles, which can each contain more than 7'000 atoms at masses greater than 170'000 dalton. They propagate in a Schrödinger cat state with a macroscopicity of $μ$ = 15.5, surpassing all previous experiments by an order of magnitude and providing the most stringent exclusion limit for generic macrorealistic modifications of the Schrödinger equation to date.
title Probing quantum mechanics using nanoparticle Schrödinger cats
topic Quantum Physics
url https://arxiv.org/abs/2507.21211