Publication record · 18.cifr/2017.bernien.rydberg-51-atom

Probing many-body dynamics on a 51-atom quantum simulator

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Hannes Bernien (Harvard University), Sylvain Schwartz (Harvard University), Alexander Keesling (Harvard University), Harry Levine (Harvard University), Ahmed Omran (Harvard University), Mikhail D. Lukin (Harvard University)

RAI18.cifr/2017.bernien.rydberg-51-atom

Nature· 2017· doi:10.1038/nature24622

Controllable, coherent many-body systems can provide insights into the fundamental properties of quantum matter, enable the realization of new exotic quantum phases and could ultimately lead to computational systems that outperform existing computers based on classical approaches. Here we demonstrate a programmable quantum simulator based on defect-free arrays of up to 51 atoms trapped in optical tweezers, where interactions are enabled by excitation to Rydberg states.

rydberg atomsquantum simulatormany-body dynamicsoptical tweezersquantum phase transition

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Simulating real-time quantum dynamics of strongly-interacting many-body systems is computationally intractable classically for >30 qubits. Experimentalists lacked a programmable coherent quantum device large enough to probe quantum thermalization and non-equilibrium phases where classical simulation fails.

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This paper demonstrates a 51-atom programmable quantum simulator using neutral Rb atoms in optical tweezers with individually controlled Rydberg blockade interactions. It is the first experimental realization at this scale to observe coherent Z2-ordered oscillations challenging thermalization theory, with site-resolved readout at 51 sites unprecedented at the time.

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