CORYGAS

Strongly Correlated Ultracold Rydberg Gases

 Coordinatore RUPRECHT-KARLS-UNIVERSITAET HEIDELBERG 

 Organization address address: SEMINARSTRASSE 2
city: HEIDELBERG
postcode: 69117

contact info
Titolo: Dr.
Nome: Verena
Cognome: Schultz-Coulon
Email: send email
Telefono: +49 6221 54 2424
Fax: +49 6221 54 3599

 Nazionalità Coordinatore Germany [DE]
 Totale costo 167˙390 €
 EC contributo 167˙390 €
 Programma FP7-PEOPLE
Specific programme "People" implementing the Seventh Framework Programme of the European Community for research, technological development and demonstration activities (2007 to 2013)
 Code Call FP7-PEOPLE-2011-IEF
 Funding Scheme MC-IEF
 Anno di inizio 2012
 Periodo (anno-mese-giorno) 2012-06-01   -   2014-05-31

 Partecipanti

# participant  country  role  EC contrib. [€] 
1    RUPRECHT-KARLS-UNIVERSITAET HEIDELBERG

 Organization address address: SEMINARSTRASSE 2
city: HEIDELBERG
postcode: 69117

contact info
Titolo: Dr.
Nome: Verena
Cognome: Schultz-Coulon
Email: send email
Telefono: +49 6221 54 2424
Fax: +49 6221 54 3599

DE (HEIDELBERG) coordinator 167˙390.40

Mappa


 Word cloud

Esplora la "nuvola delle parole (Word Cloud) per avere un'idea di massima del progetto.

atomic    quantum    exotic    create    ultimately    laser    interacting    dense    atoms    gases    plasma    interacted    physics    cold    rydberg    corygas    polariton    excited    ultra    mechanisms    correlations    light    excitations    polaritons    interactions    ultracold    studying    scientists    ground    shedding    phases    coupled    gas    optical    statistics    correlated    body    self   

 Obiettivo del progetto (Objective)

'Neutral atoms in highly-excited (Rydberg) states are strongly-polarisable particles, which due to their exaggerated properties can experience quantum effects and interactions over macroscopic distances. Many-body systems of Rydberg atoms offer unique opportunities to create and investigate strong correlations in ultra-cold atomic samples. This work will be devoted to studying the collective effects that arise in the excitation of a dense cold gas towards Rydberg states. Many-body effects caused by Rydberg enhanced interactions can manifest themselves in dramatic ways, such as the generation of entanglement, structure formation, and exotic quantum phases.

A new experimental system for studying strongly correlated quantum matter is available for this project. We will investigate the emergence of crystalline order in the excited Rydberg gas due to interactions. A new method to directly image the Rydberg atoms will be developed for this purpose. Finally, the interactions properties of Rydberg atoms will be mapped onto the degenerate, long-lived ground state bath. This will extend the field of ultra-cold gases to the study of new strongly-correlated many-body phases of matter, shedding new light on self-ordering mechanisms and ultimately creating a powerful new platform for quantum information science. It will raise the applicant's international recognition, and establish him inside Europe as a leading researcher in this new and quickly evolving field.'

Introduzione (Teaser)

EU-funded scientists used laser fields to generate quantum matter with novel, crystal-like properties.

Descrizione progetto (Article)

Ultracold atomic gases are ideally suited for exploring the quantum physics of many-body systems and for investigating matter and exotic quantum phenomena. The EU-funded project 'Strongly correlated ultracold Rydberg gases' (http://tinyurl.com/njhk4dq (CORYGAS)) made use of the extraordinary properties of highly excited Rydberg atoms in dense atomic gases to explore the realm of strongly correlated many-body physics.

To create Rydberg atoms, scientists used lasers to illuminate a dense ensemble of cold gas atoms. These ground-state atoms were excited in the Rydberg state and strongly interacted with each other, leading to spatial correlations.

Scientists observed polaritons propagating through the excited ultracold atomic gas coupled via an electromagnetically induced transparency resonance. Strong long-range interactions between Rydberg excitations gave rise to polariton blockade, resulting in large optical nonlinearities, and modified polariton number statistics. By combining optical imaging and high-fidelity detection of the Rydberg polaritons, the team investigated this coupled atom-light system. The employed techniques greatly facilitated observation of energy transport.

Full counting statistics provided valuable information on Rydberg interacting many-body systems. In particular, novel insight was obtained about the formation mechanism of correlations in such systems. Correlated systems comprising of few excitations (aggregates) were formed through sequential growth. These excitations interacted with each other to compensate for laser detuning. Furthermore, scientists observed a sudden and spontaneous evolution of an initially correlated gas of repulsively interacting Rydberg atoms to an ultracold plasma. Rydberg-Rydberg interactions were found to strongly affect the dynamics of plasma formation.

CORYGAS showed that Rydberg interactions in ultracold gases are helping to study new strongly correlated many-body phases of matter and are shedding new light on self-ordering mechanisms. Ultimately, they are offering a fertile ground for investigating entangled states of atoms that should find many applications in quantum information systems.

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