CRYST^3 | ATOM-LIGHT CRYSTALS IN PHOTONIC CRYSTALS

Summary
All automated systems require sensing of the surrounding environment. The rising relevance of artificial intelligence in society demands sensors that are accurate, light-weighted, cheap and robust. Among the best laboratory sensors - in a broad sense including clocks, accelerometers, gyroscopes…- , those based on individual atoms stand out for their phenomenal stability and accuracy, but most are bulky and fragile, nearly all are expensive.
CRYST3 envisions a future technology where the core element, the sensor head containing the atoms, is greatly reduced in size and cost, and made more robust and more suitable for industrialization. The project will deliver the seminal contribution of a novel material where individual alkali atoms at microkelvin temperatures are encapsulated in the hollow core of a photonic crystal optical fiber, fully functionalized, hermetically sealed and integrated with light sources.
In this novel material, we expect novel physical phenomena: atoms acquire long-range interactions that are mediated by the light field and tailored through the design of the fiber; spontaneous spatial order of the atoms, akin to crystallization, emerge; light is scattered by the atoms in a collective manner that results in superradiant emission.
CRYST3 will generate the first prototype of the novel material, fully operational and customized, from numerical design, manufacturing, post-processing and testing, to industrialization assessment by a leading photonic company. The technological advancements will be intertwined with theoretical analysis and experimental demonstrations of novel loading, trapping and cooling techniques to create a large sample of ultracold atoms in a hollow-core fiber, which will serve as the platform for the scientific breakthroughs of: (1) cooling the atoms inside the fiber, (2) observing their emergent self-ordering and (3) detecting the superradiant properties of the emitted light.
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More information & hyperlinks
Web resources: https://cordis.europa.eu/project/id/964531
Start date: 01-04-2021
End date: 31-03-2025
Total budget - Public funding: 3 586 428,75 Euro - 3 586 428,00 Euro
Cordis data

Original description

All automated systems require sensing of the surrounding environment. The rising relevance of artificial intelligence in society demands sensors that are accurate, light-weighted, cheap and robust. Among the best laboratory sensors - in a broad sense including clocks, accelerometers, gyroscopes…- , those based on individual atoms stand out for their phenomenal stability and accuracy, but most are bulky and fragile, nearly all are expensive.
CRYST3 envisions a future technology where the core element, the sensor head containing the atoms, is greatly reduced in size and cost, and made more robust and more suitable for industrialization. The project will deliver the seminal contribution of a novel material where individual alkali atoms at microkelvin temperatures are encapsulated in the hollow core of a photonic crystal optical fiber, fully functionalized, hermetically sealed and integrated with light sources.
In this novel material, we expect novel physical phenomena: atoms acquire long-range interactions that are mediated by the light field and tailored through the design of the fiber; spontaneous spatial order of the atoms, akin to crystallization, emerge; light is scattered by the atoms in a collective manner that results in superradiant emission.
CRYST3 will generate the first prototype of the novel material, fully operational and customized, from numerical design, manufacturing, post-processing and testing, to industrialization assessment by a leading photonic company. The technological advancements will be intertwined with theoretical analysis and experimental demonstrations of novel loading, trapping and cooling techniques to create a large sample of ultracold atoms in a hollow-core fiber, which will serve as the platform for the scientific breakthroughs of: (1) cooling the atoms inside the fiber, (2) observing their emergent self-ordering and (3) detecting the superradiant properties of the emitted light.

Status

SIGNED

Call topic

FETOPEN-01-2018-2019-2020

Update Date

27-04-2024
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Horizon 2020
H2020-EU.1. EXCELLENT SCIENCE
H2020-EU.1.2. EXCELLENT SCIENCE - Future and Emerging Technologies (FET)
H2020-EU.1.2.1. FET Open
H2020-FETOPEN-2018-2020
FETOPEN-01-2018-2019-2020 FET-Open Challenging Current Thinking