10-Qubit Entanglement and Parallel Logic Operations with a Superconducting Circuit

Song, Cunxian; Xu, Kai; Liu, Wuxin; Yang, Chui‐Ping; Zheng, Shi‐Biao; Deng, Hui; Xie, Qiwei; Huang, Keqiang; Guo, Qiujiang; Zhang, Libo; Zhang, Pengfei; Xu, Da; Zheng, Dewen; Zhu, Xiaobo; Wang, H.; Chen, Y.-A.; Lu, Chao‐Yang; Han, Siyuan; Pan, Jian-Wei

doi:10.1103/physrevlett.119.180511

Cited by 394 publications

(260 citation statements)

References 52 publications

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“…In theory, such a device can solve certain problems, such as factoring, exponentially faster than classical digital computers. The leading technological prototypes are based on superconducting transmon qubits containing on the order of 10 qubits [1][2][3][4]. IBM provides public access to such a quantum processor through the IBM Quantum Experience (IBMQX) [5].…”

Section: Introductionmentioning

confidence: 99%

Gate-error analysis in simulations of quantum computers with transmon qubits

et al. 2017

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In the model of gate-based quantum computation, the qubits are controlled by a sequence of quantum gates. In superconducting qubit systems, these gates can be implemented by voltage pulses. The success of implementing a particular gate can be expressed by various metrics such as the average gate fidelity, the diamond distance, and the unitarity. We analyze these metrics of gate pulses for a system of two superconducting transmon qubits coupled by a resonator, a system inspired by the architecture of the IBM Quantum Experience. The metrics are obtained by numerical solution of the time-dependent Schrödinger equation of the transmon system. We find that the metrics reflect systematic errors that are most pronounced for echoed cross-resonance gates, but that none of the studied metrics can reliably predict the performance of a gate when used repeatedly in a quantum algorithm.

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Section: Introductionmentioning

confidence: 99%

Gate-error analysis in simulations of quantum computers with transmon qubits

et al. 2017

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“…Based on circuit QED, many proposals have been presented for implementing quantum state transfer between SC qubits [1,[13][14][15], quantum logic gates of SC qubits [16][17][18][19][20][21], and entanglement in SC qubits [22][23][24][25][26][27][28]. By using SC qubits, the experimental demonstrations of single-qubit gates [29,30], two-qubit gates [31,32], three-qubit gates [33,34], 10-qubit entanglement [35], 12-qubit entanglement [36], 18-qubit entanglement [37], and 20-qubit Schrödinger cat states [37] have been reported. Moreover, quantum teleportation between two distant SC qubits [38], quantum state transfer in a SC qubit chain [39], entanglement swapping in superconducting circuit [40], and quantum walks in a 12-qubit superconducting processor [41] have been realized in experiments.…”

Section: Introductionmentioning

confidence: 99%

Transferring entangled states of photonic cat-state qubits in circuit QED

et al. 2020

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We propose a method for transferring quantum entangled states of two photonic cat-state qubits (cqubits) from two microwave cavities to the other two microwave cavities. This proposal is realized by using four microwave cavities coupled to a superconducting flux qutrit. Because of using four cavities with different frequencies, the inter-cavity crosstalk is significantly reduced. Since only one coupler qutrit is used, the circuit resources is minimized. The entanglement transfer is completed with a single-step operation only, thus this proposal is quite simple. The third energy level of the coupler qutrit is not populated during the state transfer, therefore decoherence from the higher energy level is greatly suppressed. Our numerical simulations show that high-fidelity transfer of two-cqubit entangled states from two transmission line resonators to the other two transmission line resonators is feasible with current circuit QED technology. This proposal is universal and can be applied to accomplish the same task in a wide range of physical systems, such as four microwave or optical cavities, which are coupled to a natural or artificial three-level atom.

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“…Our work shows how errors can be suppressed via additional measurements, potentially offering an alternative to more advanced error-correction techniques, which are typically difficult to implement and require large resource overhead. These methods can be directly transferred to other systems, such as planar superconducting platforms and ion traps, where significant numbers of qubits can be routinely controlled and read out [1,2,[24][25][26], potentially paving the way for larger more complex quantum simulations in the near future.…”

Section: Introductionmentioning

confidence: 99%

Quantum Computer Simulates Excited States of Molecule

Sim

Romero

Johnson

et al. 2018

Physics

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Harnessing the full power of nascent quantum processors requires the efficient management of a limited number of quantum bits with finite coherent lifetimes. Hybrid algorithms, such as the variational quantum eigensolver (VQE), leverage classical resources to reduce the required number of quantum gates. Experimental demonstrations of VQE have resulted in calculation of Hamiltonian ground states, and a new theoretical approach based on a quantum subspace expansion (QSE) has outlined a procedure for determining excited states that are central to dynamical processes. We use a superconducting-qubit-based processor to apply the QSE approach to the H 2 molecule, extracting both ground and excited states without the need for auxiliary qubits or additional minimization. Further, we show that this extended protocol can mitigate the effects of incoherent errors, potentially enabling larger-scale quantum simulations without the need for complex error-correction techniques.

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10-Qubit Entanglement and Parallel Logic Operations with a Superconducting Circuit

Cited by 394 publications

References 52 publications

Gate-error analysis in simulations of quantum computers with transmon qubits

Gate-error analysis in simulations of quantum computers with transmon qubits

Transferring entangled states of photonic cat-state qubits in circuit QED

Quantum Computer Simulates Excited States of Molecule

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