Robust and Resource-Efficient Microwave Near-Field Entangling 
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 Gate

Zarantonello, Giorgio; Hahn, H.; Morgner, Jonathan; Schulte, Marius; Bautista-Salvador, A.; Werner, Reinhard; Hammerer, Klemens; Ospelkaus, C.

doi:10.1103/physrevlett.123.260503

Cited by 95 publications

(75 citation statements)

References 44 publications

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“…A number of experimental demonstrations of high-fidelity microwave-based entangling gates between ions have been carried out [ 61 ], [ 77 ]–[ 80 ]. In general, these gates are slower (~ ms duration) than laser-based entangling gates, which can be performed in tens or hundreds of μ s (and some as fast as a few μ s [ 81 ]).…”

Section: Coherent Control Of Quantum Processors Using Microwave Techniquesmentioning

confidence: 99%

Microwaves in Quantum Computing

2021

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Quantum information processing systems rely on a broad range of microwave technologies and have spurred development of microwave devices and methods in new operating regimes. Here we review the use of microwave signals and systems in quantum computing, with specific reference to three leading quantum computing platforms: trapped atomic ion qubits, spin qubits in semiconductors, and superconducting qubits. We highlight some key results and progress in quantum computing achieved through the use of microwave systems, and discuss how quantum computing applications have pushed the frontiers of microwave technology in some areas. We also describe open microwave engineering challenges for the construction of large-scale, fault-tolerant quantum computers.

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Section: Coherent Control Of Quantum Processors Using Microwave Techniquesmentioning

confidence: 99%

Microwaves in Quantum Computing

2021

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“…ZGP gates cannot be performed directly on the low-decoherence clock qubits, but are insensitive to the absolute magnetic field offset. Two-qubit gates have been performed both with lasers [56,57,59,62] and rf [80][81][82][83][84] as well as between ions of different elements [61,[85][86][87]. Due to the weak motional coupling rf multi-qubit gates are considerably slower than laser gates.…”

Section: Qubit Manipulationmentioning

confidence: 99%

Quantum computing hardware in the cloud: Should a computational chemist care?

Rossi

Baity

Schäfer

et al. 2021

Int J of Quantum Chemistry

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Within the last decade much progress has been made in the experimental realization of quantum computing hardware based on a variety of physical systems. Rapid progress has been fuelled by the conviction that sufficiently powerful quantum machines will herald enormous computational advantages in many fields, including chemical research.A quantum computer capable of simulating the electronic structures of complex molecules would be a game changer for the design of new drugs and materials. Given the potential implications of this technology, there is a need within the chemistry community to keep abreast with the latest developments as well as becoming involved in experimentation with quantum prototypes. To facilitate this, here we review the types of quantum computing hardware that have been made available to the public through cloud services. We focus on three architectures, namely superconductors, trapped ions and semiconductors. For each one we summarize the basic physical operations, requirements and performance. We discuss to what extent each system has been used for molecular chemistry problems and highlight the most pressing hardware issues to be solved for a chemistry-relevant quantum advantage to eventually emerge. | INTRODUCTIONThis year marks exactly 40 years since Richard Feynman famously said [1]: "Nature isn't classical, dammit, and if you want to make a simulation of nature, you'd better make it quantum mechanical, and by golly it's a wonderful problem, because it doesn't look so easy." On the one hand, the visionary physicist anticipated the possibility (and the inherent difficulty) of building a new type of computing apparatus operating according to the laws of quantum mechanics. On the other hand, he had immediately identified one of its most useful areas of application, i.e. simulations of chemical and physical systems.Computational chemists will indeed benefit from future quantum computers for calculations of molecular energies to within chemical accuracy, defined to be the target accuracy necessary to estimate chemical reaction rates at room temperature (≈1 kcal/mol) [2]. Fully-fledged, errorfree quantum systems will enable predictions and simulations that are not possible today in terms of both accuracy and speed. This could have a revolutionary impact on the design of drugs, catalysts and materials by allowing computational methods to replace lengthy and expensive experimental procedures. Unfortunately, we are still in the infancy of the development of quantum computing technology and a machine that provides a quantum advantage in molecular chemistry over classical super-computers has not emerged yet. However, the progress in handling increasingly complex molecular and material chemistry has been relentless. Small-scale quantum machines developed by academic or corporate research centres have been initially used to simulate simple diatomic or triatomic molecules made up of just H and He atoms [3][4][5]. Recently, more powerful quantum computers have been used to simulate larger compounds conta...

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“…Moreover, the addition of control permits the introduction of noise and drift‐robustness even in complex multi‐ion settings. [ 16–21 ]…”

Section: Introductionmentioning

confidence: 99%

Numeric Optimization for Configurable, Parallel, Error‐Robust Entangling Gates in Large Ion Registers

Bentley¹,

Ball²,

Biercuk

et al. 2020

Adv Quantum Tech

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A class of entangling gates for trapped atomic ions is studied and the use of numeric optimization techniques to create a wide range of fast, error‐robust gate constructions is demonstrated. A numeric optimization framework is introduced targeting maximally‐ and partially‐entangling operations on ion pairs, multi‐ion registers, multi‐ion subsets of large registers, and parallel operations within a single register. Ions are assumed to be individually addressed, permitting optimization over amplitude‐ and phase‐modulated controls. Calculations and simulations demonstrate that the inclusion of modulation of the difference phase for the bichromatic drive used in the Mølmer–Sørensen gate permits approximately time‐optimal control across a range of gate configurations, and when suitably combined with analytic constraints can also provide robustness against key experimental sources of error. The impact of experimental constraints such as bounds on coupling rates or modulation band‐limits on achievable performance is further demonstrated. Using a custom optimization engine based on TensorFlow, for optimizations on ion registers up to 20 ions, time‐to‐solution of order tens of minutes using a local‐instance laptop is also demonstrated, allowing computational access to system‐scales relevant to near‐term trapped‐ion devices.

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Robust and Resource-Efficient Microwave Near-Field Entangling Be+9 Gate

Cited by 95 publications

References 44 publications

Microwaves in Quantum Computing

Microwaves in Quantum Computing

Quantum computing hardware in the cloud: Should a computational chemist care?

Numeric Optimization for Configurable, Parallel, Error‐Robust Entangling Gates in Large Ion Registers

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