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Contenido archivado el 2024-06-18

Emulators of Quantum Frustrated Magnetism

Descripción del proyecto


Challenging current Thinking
Simulation, characterization, and manipulation, in a highly controlled fashion, of Hamiltonian models of frustrated quantum magnets.

Among complex systems with emergent behaviours, frustrated quantum magnets are predicted to exhibit novel, highly nontrivial phases of matter that may play a major role in future and emerging quantum technologies such as the synthesis of innovative materials for energy harnessing and storage, entanglement-enhanced metrology, and topological quantum computing.Unfortunately due to the intrinsic levels of noise in "natural" compounds, the controlled realization, characterization, and manipulation of frustrated quantum magnets appear exceedingly demanding. On the other hand, we are now entering an advanced stage of development of quantum emulators, engineered quantum systems that realize model Hamiltonians of increasing complexity in a controlled fashion. Cutting-edge technologies for quantum emulation science include cold atoms in optical lattices, trapped ultracold ions (Coulomb crystals), NV centres in diamond, and photonic circuits. By developing, comparing, and integrating these four different atom-optical platforms, project EQuaM's breakthrough is the controlled experimental emulation of fundamental model Hamiltonians for frustrated quantum magnetism, both in nontrivial lattice geometries and for competing long-range interactions, and the characterization of their phase diagrams, targeting fundamental features such as spin liquid phases, global topological order, and fractional excitations. By achieving this objective, EQuaM's groundbreaking contribution to the long-term vision in Information and Communication Technologies (ICT) is the efficient quantum emulation, not admitting efficient classical computational counterparts, of many-body quantum systems with essential elements of complexity. Besides providing crucial insights in the physics of complex many-body systems, it will be a foundational step in the realization of large-scale architectures for topologically protected quantum computation and information.

Convocatoria de propuestas

FP7-ICT-2013-C
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Régimen de financiación

CP - Collaborative project (generic)

Coordinador

UNIVERSITA DEGLI STUDI DI SALERNO
Aportación de la UE
€ 366 400,00
Dirección
VIA GIOVANNI PAOLO II 132
84084 Fisciano Sa
Italia

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Región
Sud Campania Salerno
Tipo de actividad
Higher or Secondary Education Establishments
Contacto administrativo
Fabrizio Illuminati (Prof.)
Enlaces
Coste total
Sin datos

Participantes (7)