Quantum Ising Hamiltonian Programming in Trio, Quartet, and Sextet Qubit Systems

Kim, Minhyuk; Song, Yunheung; Kim, Jaewan; Ahn, Jaewook

doi:10.1103/prxquantum.1.020323

Cited by 30 publications

(21 citation statements)

References 34 publications

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“…N Ryd : Number of atoms in the Rydberg excited state. Considering the Rydberg-atom blockade regime [12], we use various connected graphs consisting of vertices and edges that represent atoms and blockaded couplings [13] respectively, as illustrated in Fig. 1 (a)-(c).…”

Section: Research Methods: Collecting Rydberg Quantum Simulation Datamentioning

confidence: 99%

“…The second term U (r jk ) ≡ C 6 /| r jk | 6 corresponds to the van der Waals interaction between two Rydberg atoms, where r jk ≡ r j − r k . nj = |1 j 1| j is the excitation number [12,13]. In the graphs representing atomic arrangements, we set the length of the edges to be d = 8 µm, which is within the range of the Rydberg-blockade radius d < r b ≡ |C 6 / Ω| 1/6 .…”

Section: Research Methods: Collecting Rydberg Quantum Simulation Datamentioning

confidence: 99%

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Machine learning identification of symmetrized base states of Rydberg atoms

Chong,

Kim,

Ahn

et al. 2021

Preprint

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Studying the complex quantum dynamics of interacting many-body systems is one of the most challenging areas in modern physics. Here, we use machine learning (ML) models to identify the symmetrized base states of interacting Rydberg atoms of various atom numbers (up to six) and geometric configurations. To obtain the data set for training the ML classifiers, we generate Rydberg excitation probability profiles that simulate experimental data by utilizing Lindblad equations that incorporate laser intensities and phase noise. Then, we classify the data sets using support vector machines (SVMs) and random forest classifiers (RFCs). With these ML models, we achieve high accuracy of up to 100% for data sets containing only a few hundred samples, especially for the closed atom configurations such as the pentagonal (five atoms) and hexagonal (six atoms) systems. The results demonstrate that computationally cost-effective ML models can be used in the identification of Rydberg atom configurations.

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Section: Research Methods: Collecting Rydberg Quantum Simulation Datamentioning

confidence: 99%

Section: Research Methods: Collecting Rydberg Quantum Simulation Datamentioning

confidence: 99%

Machine learning identification of symmetrized base states of Rydberg atoms

Chong,

Kim,

Ahn

et al. 2021

Preprint

Self Cite

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“…While simulations of Quantum Chromodynamics are still many years off, digital quantum simulations of 1 + 1 and 2 + 1 dimensional field theories are already in progress [32][33][34][35][36][37][38][39][40][41][42][43]. Simulations of the Transverse Ising model (TIM) [36,[44][45][46][47][48][49][50][51][52][53][54][55][56] and some simpler gauge theories such as the Schwinger model have been a major focus of qubit based computers [15,24,33,38,57]. Compact scalar Quantum Electrodynamics (sQED) in (1 + 1)d has implementations proposed for optical lattices [8,9].…”

Section: Introductionmentioning

confidence: 99%

Prospects for Simulating a Qudit Based Model of (1+1)d Scalar QED

Gustafson

2021

Preprint

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We present a gauge invariant digitization of (1 + 1)d scalar quantum electrodynamics for an arbitrary spin truncation for qudit-based quantum computers. We provide a construction of the Trotter operator in terms of a universal qudit-gate set. The cost savings of using a qutrit based spin-1 encoding versus a qubit encoding are illustrated. We show that a simple initial state could be simulated on current qutrit based hardware using noisy simulations for two different native gate set.

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“…In this Letter, we propose experimental tools for achieving fast scrambling in near-term experiments with one-dimensional (1D) arrays of optically trapped neutral atoms [14][15][16][17][18][19][20][21][22][23][24][25]. By rapidly shuffling atoms using optical tweezers it is possible to implement a broad family of nonlocal, sparsely coupled quantum circuits that realize fast scrambling quantum channels [2][3][4].…”

mentioning

confidence: 99%

Deterministic Fast Scrambling with Neutral Atom Arrays

et al. 2021

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Fast scramblers are dynamical quantum systems that produce many-body entanglement on a timescale that grows logarithmically with the system size N . We propose and investigate a family of deterministic, fast scrambling quantum circuits realizable in near-term experiments with arrays of neutral atoms. We show that three experimental tools -nearest-neighbor Rydberg interactions, global single-qubit rotations, and shuffling operations facilitated by an auxiliary tweezer array -are sufficient to generate nonlocal interaction graphs capable of scrambling quantum information using only O(log N ) parallel applications of nearest-neighbor gates. These tools enable direct experimental access to fast scrambling dynamics in a highly controlled and programmable way and can be harnessed to produce highly entangled states with varied applications.

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Quantum Ising Hamiltonian Programming in Trio, Quartet, and Sextet Qubit Systems

Cited by 30 publications

References 34 publications

Machine learning identification of symmetrized base states of Rydberg atoms

Machine learning identification of symmetrized base states of Rydberg atoms

Prospects for Simulating a Qudit Based Model of (1+1)d Scalar QED

Deterministic Fast Scrambling with Neutral Atom Arrays

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