Many-body physics with individually controlled Rydberg atoms

Browaeys, Antoine; Lahaye, Thierry

doi:10.1038/s41567-019-0733-z

Cited by 804 publications

(594 citation statements)

References 119 publications

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“…The emerging research field of Rydberg excitons in cuprous oxide is facilitating an exciting crossover between two previously siloed disciplines: cold-atom physics and semiconductor quantum optics. The coherent spectroscopy of Rydberg states in gas-phase atomic systems has garnered great recent interest, with applications in the measurement of electromagnetic fields from DC to terahertz frequencies [1,2], quantum simulation [3] and computation [4], and quantum optics [5]. There is clear interest in observing similar states in semiconductor systems, where half a century of development in state-of-theart nano-fabrication techniques provide capabilities that go way beyond those available in the gas phase.…”

Section: Introductionmentioning

confidence: 99%

Giant Rydberg Excitons in Synthetic and Artificial Cuprous Oxide

Lynch

Hodges

Langbein

et al. 2018

2018 20th International Conference on Transparent Optical Networks (ICTON)

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High-lying Rydberg states of Mott-Wannier excitons are receiving considerable interest due to the possibility of adding long-range interactions to the physics of exciton-polaritons. Here, we study Rydberg excitation in bulk synthetic cuprous oxide grown by the optical float zone technique and compare the result with natural samples. X-ray characterization confirms both materials are mostly single crystal, and mid-infrared transmission spectroscopy revealed little difference between synthetic and natural material. The synthetic samples show principal quantum numbers up to n = 10, exhibit additional absorption lines, plus enhanced spatial broadening and spatial inhomogeneity. Room temperature and cryogenic photoluminescence measurements reveal a significant excess of copper vacancies in the synthetic material. These measurements provide a route towards achieving high-n excitons in synthetic crystals, opening a route to scalable quantum devices.

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Section: Introductionmentioning

confidence: 99%

Giant Rydberg Excitons in Synthetic and Artificial Cuprous Oxide

Lynch

Hodges

Langbein

et al. 2018

2018 20th International Conference on Transparent Optical Networks (ICTON)

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“…Each qubit of the register then behaves as a spin whose states are |↓ = |0 and |↑ = |1 . Depending on the Rydberg states that are involved in the process, the spins experience different types of interactions that translate into different Hamiltonians [6]. The most studied one is the Ising model, which is obtained when the |↓ state is one of the ground states and the |↑ a Rydberg state [25,26,27,28].…”

Section: Analog Quantum Processingmentioning

confidence: 99%

“…Fundamental research on quantum information processing platforms using neutral atoms has been going on for years, and has led to impressive scientific results such as the simulation of highly complex quantum systems well above 100 qubits, beyond the reach of classical high performance computers [6]. Only recently did it become possible to contemplate manufacturing devices for commercial use thanks to continuous progress in design and engineering.…”

Section: Introductionmentioning

confidence: 99%

Quantum computing with neutral atoms

Henriet¹,

Béguin²,

Signoles³

et al. 2020

Quantum

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280

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The manipulation of neutral atoms by light is at the heart of countless scientific discoveries in the field of quantum physics in the last three decades. The level of control that has been achieved at the single particle level within arrays of optical traps, while preserving the fundamental properties of quantum matter (coherence, entanglement, superposition), makes these technologies prime candidates to implement disruptive computation paradigms. In this paper, we review the main characteristics of these devices from atoms / qubits to application interfaces, and propose a classification of a wide variety of tasks that can already be addressed in a computationally efficient manner in the Noisy Intermediate Scale Quantum\cite{Preskill_NISQ} era we are in. We illustrate how applications ranging from optimization challenges to simulation of quantum systems can be explored either at the digital level (programming gate-based circuits) or at the analog level (programming Hamiltonian sequences). We give evidence of the intrinsic scalability of neutral atom quantum processors in the 100-1,000 qubits range and introduce prospects for universal fault tolerant quantum computing and applications beyond quantum computing.

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“…Here, we consider integration of the recently developed DMD techniques in controlling optical potentials 13,[35][36][37][38] to optical lattices, and calibrate the platform towards precise programmable quantum simulations. We develop an efficient algorithm, which can systematically construct an inhomogeneous optical potential to precisely simulate a given tight binding lattice model, i.e., both the onsite energies and the tunnelings are made precisely programmable.…”

Section: Introductionmentioning

confidence: 99%

Precise programmable quantum simulations with optical lattices

Qiu

Zou

Qi³

et al. 2020

npj Quantum Inf

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We present an efficient approach to precisely simulate tight binding models with optical lattices, based on programmable digital-micromirror-device (DMD) techniques. Our approach consists of a subroutine of Wegner-flow enabled precise extraction of a tight-binding model for a given optical potential, and a reverse engineering step of adjusting the potential for a targeting model, for both of which we develop classical algorithms to achieve high precision and high efficiency. With renormalization of Wannier functions and high band effects systematically calibrated in our protocol, we show the tight-binding models with programmable onsite energies and tunnelings can be precisely simulated with optical lattices integrated with the DMD techniques. With numerical simulation, we demonstrate that our approach would facilitate quantum simulation of localization physics with adequate programmability and atom-based boson sampling for illustration of quantum computational advantage. We expect this approach would pave a way towards large-scale and precise programmable quantum simulations based on optical lattices.

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Many-body physics with individually controlled Rydberg atoms

Cited by 804 publications

References 119 publications

Giant Rydberg Excitons in Synthetic and Artificial Cuprous Oxide

Giant Rydberg Excitons in Synthetic and Artificial Cuprous Oxide

Quantum computing with neutral atoms

Precise programmable quantum simulations with optical lattices

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