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Nanodesigning of  Atomic and MolEcular QUAntum Matter

Nanodesigning of Atomic and MolEcular QUAntum Matter

Objective

The Project investigates ultracold atom/molecule quantum matter technology for quantum information computational tasks. Our efforts concentrate on atoms/molecules confined in periodic nanostructures, either externally imposed by optical lattices, or self-generated by atomic/molecular interactions. Parallel quantum processing in periodic nanostructures is expected to lead to significant advances in different areas of quantum information. The Project aims at developing novel techniques for quantum engineering and quantum control of ultracold atoms and molecules confined in the periodic nanostructures. An innovative aspect is the development of appropriate tools for achieving quantum control of strongly correlated many body systems at the nanoscale by exploiting moderate- and long-range quantum mechanical interactions. Strongly correlated interacting systems offer a level of computational power that cannot be reached with traditional qubits based on spin, or hyperfine atomic states. Moderate and long, range interactions will be exploited in few body quantum systems in order to produce fast quantum gates using novel robust qubit and/or qudit concepts and using quantum states with topological order, all of them highly relevant for next generation quantum information implementations.The objectives rely on the nanodesign of atomic/molecular quantum matter at the mesoscopic scale of few-body systems. Generation and detection of multiparticle quantum entanglement, robusteness of non-traditional qubits, quantum memories characterise our investigation. The Project will implement new quantum information technologies by achieving the following breakthroughs: characterizing long range interacting systems for optimal quantum information; realizing individual manipulation integrated in proper algorithms; designing new protected qubits or quantum information processors based on long range interactions; developing techniques for topological quantum computation; creating multi-partimulti-particle entanglement for quantum simulation investigations. At the present stage of the quantum information development our objectives are unique for the optical lattice quantum matter technology. As far as the visionary aspects are concerned, the technological and conceptual advances resulting from the planned investigations on multiparticle entanglement, topological structures and nano-optical engineering may lead to the identification of new directions and alternative approaches towards scalable and miniaturisable quantum information processing.

Coordinator

CONSIGLIO NAZIONALE DELLE RICERCHE

Address

Piazzale Aldo Moro 7
00185 Roma

Italy

Activity type

Higher or Secondary Education Establishments

EU Contribution

€ 469 155

Administrative Contact

FRANCESCA USALA (Dr.)

Participants (8)

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UNIVERSITAET INNSBRUCK

Austria

EU Contribution

€ 270 000

EIDGENOESSISCHE TECHNISCHE HOCHSCHULE ZUERICH

Switzerland

EU Contribution

€ 400 000

MAX-PLANCK-GESELLSCHAFT ZUR FORDERUNG DER WISSENSCHAFTEN EV

Germany

EU Contribution

€ 334 960

JOHANNES GUTENBERG-UNIVERSITAT MAINZ

Germany

EU Contribution

€ 65 040

FUNDACIO INSTITUT DE CIENCIES FOTONIQUES

Spain

EU Contribution

€ 199 800

LABORATORIO EUROPEO DI SPETTROSCOPIE NON LINEARI

Italy

EU Contribution

€ 401 800

VILNIAUS UNIVERSITETAS

Lithuania

EU Contribution

€ 150 000

INSTYTUT FIZYKI POLSKIEJ AKADEMII NAUK

Poland

EU Contribution

€ 150 000

Project information

Grant agreement ID: 225187

Status

Closed project

  • Start date

    1 January 2009

  • End date

    30 April 2012

Funded under:

FP7-ICT

  • Overall budget:

    € 3 230 625

  • EU contribution

    € 2 440 755

Coordinated by:

CONSIGLIO NAZIONALE DELLE RICERCHE

Italy