Demonstration of long-range correlations via susceptibility measurements in a one-dimensional superconducting Josephson spin chain

Tennant, Daniel; Dai, Xianzhe; Martinez, Antonio; Trappen, Robbyn; Melanson, Denis; Yurtalan, Muhammet Ali; Tang, Yongchao; Bedkihal, Salil; Yang, Rui; Новиков, Сергей Петрович; Grover, Jeffrey A.; Disseler, Steven M.; Basham, James I.; Das, Rabindra Nath; Kim, David K.; Melville, Alexander; Niedzielski, Bethany; Weber, Steven; Yoder, Jonilyn; Kerman, Andrew J.; Mozgunov, Evgeny; Lidar, Daniel A.; Lupaşcu, Adrian

doi:10.1038/s41534-022-00590-8

Cited by 7 publications

(7 citation statements)

References 58 publications

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“…We present a solution to the exponential decrease in performance with the length of the repetition code: instead of a ferromagnetic repetition code, one needs to use a paramagnetic chain in its ground state as the interaction mediator, together with a single well-isolated hardware qubit serving as a logical qubit. This idea has already appeared under the name of paramagnetic trees [8,9], and here we provide a theoretical justification for this approach. We observe that such a mediator is a type of perturbative gadget [10], and analyze it via an exact version of perturbation theory: a Schrieffer-Wolff transformation [11].…”

Section: Introductionmentioning

confidence: 83%

“…( 1) is impossible on a chip is that to implement it, the qubits on which H target is defined will have to be extended objects, which will lead to the failure of the qubit approximation, as well as uncontrollable levels of noise. Instead, we take inspiration from the idea of paramagnetic trees [8,9] where the qubits are well isolated and highly coherent, and the extended objects connecting different qubits are the mediators of interactions.…”

Section: Problem Settingmentioning

confidence: 99%

“…We present a construction of a scalable paramagnetic tree [8,9]. Specifically, we show that a circuit on a chip with a constant density of elements shown in Fig.…”

Section: Analytic Expressions For the Gadgetmentioning

confidence: 99%

“…Perturbative gadgets were previously used to implement a many-body interaction using only two body terms [12]. Here we use them instead to implement a long-range two-body interaction using only nearest-neighbor two-body terms [9]. The mediator can be any physical system.…”

Section: Introductionmentioning

confidence: 99%

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Precision of quantum simulation of all-to-all coupling in a local architecture

Mozgunov¹

2023

Preprint

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We present a simple 2d local circuit that implements all-to-all interactions via perturbative gadgets. We find an analytic relation between the values Jij of the desired interaction and the parameters of the 2d circuit, as well as the expression for the error in the quantum spectrum. For the relative error to be a constant , one requires an energy scale growing as n 6 in the number of qubits, or equivalently a control precision up to n −6 . Our proof is based on the Schrieffer-Wolff transformation and generalizes to any hardware. In the architectures available today, 5 digits of control precision are sufficient for n = 40, = 0.1. Comparing our construction, known as paramagnetic trees, to ferromagnetic chains used in minor embedding, we find that at chain length > 3 the performance of minor embedding degrades exponentially with the length of the chain, while our construction experiences only a polynomial decrease.

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Section: Introductionmentioning

confidence: 83%

Section: Problem Settingmentioning

confidence: 99%

“…We present a construction of a scalable paramagnetic tree [8,9]. Specifically, we show that a circuit on a chip with a constant density of elements shown in Fig.…”

Section: Analytic Expressions For the Gadgetmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Precision of quantum simulation of all-to-all coupling in a local architecture

Mozgunov¹

2023

Preprint

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“…A promising physical realisation of our model is the superconducting flux and transmon qubits. A direct ZZ interaction between flux qubits can be realised by coupling the qubits inductively, as demonstrated in quantum annealers 11,18 . There is another interesting scheme based on the inductive longitudinal coupling of the flux qubits with a common bus resonator 15,16,19 , which can be scaled up to 2D arrays 20 .…”

Section: Discussionmentioning

confidence: 99%

Scalable and robust quantum computing on qubit arrays with fixed coupling

Cykiert

Ginossar

2023

npj Quantum Inf

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We propose a scheme for scalable and robust quantum computing on two-dimensional arrays of qubits with fixed longitudinal coupling. This opens the possibility for bypassing the device complexity associated with tunable couplers required in conventional quantum computing hardware. Our approach is based on driving a subarray of qubits such that the total multi-qubit Hamiltonian can be decomposed into a sum of commuting few-qubit blocks, and efficient optimisation of the unitary evolution within each block. The driving pulses are optimised to implement a target gate on the driven qubits, and at the same time identity gates on the neighbouring undriven qubits, cancelling any unwanted evolution due to the constant qubit-qubit interaction. We show that it is possible to realise a universal set of quantum gates with high fidelity on the basis blocks, and by shifting the driving pattern one can realise an arbitrary quantum circuit on the array. Allowing for imperfect Hamiltonian characterisation, we use robust optimal control to obtain fidelities around 99.99% despite 1% uncertainty in the qubit-qubit and drive-qubit couplings, and a detuning uncertainty at 0.1% of the qubit-qubit coupling strength. This robust feature is crucial for scaling up as parameter uncertainty is significant in large devices.

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