Related papers: Direct Implementation of High-Fidelity Three-Qubit Gates for Superconducting Processor with Tunable Couplers

Direct Implementation of High-Fidelity Three-Qubit Gates for Superconducting Processor with Tunable Couplers

URL: http://arxiv.org/abs/2501.18319v1
Date: Thu, 30 Jan 2025 12:57:57 GMT
Title: Direct Implementation of High-Fidelity Three-Qubit Gates for Superconducting Processor with Tunable Couplers
Authors: Hao-Tian Liu, Bing-Jie Chen, Jia-Chi Zhang, Yong-Xi Xiao, Tian-Ming Li, Kaixuan Huang, Ziting Wang, Hao Li, Kui Zhao, Yueshan Xu, Cheng-Lin Deng, Gui-Han Liang, Zheng-He Liu, Si-Yun Zhou, Cai-Ping Fang, Xiaohui Song, Zhongcheng Xiang, Dongning Zheng, Yun-Hao Shi, Kai Xu, Heng Fan,
Abstract summary: Three-qubit gates can be constructed using combinations of single-qubit and two-qubit gates, making their independent realization unnecessary. We propose and experimentally demonstrate a high-fidelity scheme for implementing a three-qubit controlled-controlled-Z (CCZ) gate in a flip-chip superconducting quantum processor with tunable couplers.
Score: 18.682049956714156
License:
Abstract: Three-qubit gates can be constructed using combinations of single-qubit and two-qubit gates, making their independent realization unnecessary. However, direct implementation of three-qubit gates reduces the depth of quantum circuits, streamlines quantum programming, and facilitates efficient circuit optimization, thereby enhancing overall performance in quantum computation. In this work, we propose and experimentally demonstrate a high-fidelity scheme for implementing a three-qubit controlled-controlled-Z (CCZ) gate in a flip-chip superconducting quantum processor with tunable couplers. This direct CCZ gate is implemented by simultaneously leveraging two tunable couplers interspersed between three qubits to enable three-qubit interactions, achieving an average final state fidelity of $97.94\%$ and a process fidelity of $93.54\%$. This high fidelity cannot be achieved through a simple combination of single- and two-qubit gate sequences from processors with similar performance levels. Our experiments also verify that multi-layer direct implementation of the CCZ gate exhibits lower leakage compared to decomposed gate approaches. To further showcase the versatility of our approach, we construct a Toffoli gate by combining the CCZ gate with Hadamard gates. As a showcase, we utilize the CCZ gate as an oracle to implement the Grover search algorithm on three qubits, demonstrating high performance with the target probability amplitude significantly enhanced after two iterations. These results highlight the advantage of our approach, and facilitate the implementation of complex quantum circuits.

Related papers

Efficient Implementation of Arbitrary Two-Qubit Gates via Unified Control [30.657387004518604]
The native gate set governs the accuracy of basic quantum operations and dictates the complexity of implementing quantum algorithms. Here, we experimentally demonstrate a unified and highly versatile gate scheme capable of generating arbitrary two-qubit gates. We achieve high fidelities averaging $99.37 pm 0.07%$ across a wide range of commonly used two-qubit unitaries. Our results highlight that fully exploiting the capabilities of a single interaction can yield a comprehensive and highly accurate gate set.
arXiv Detail & Related papers (2025-02-05T21:00:34Z)
Quantum Compiling with Reinforcement Learning on a Superconducting Processor [55.135709564322624]
We develop a reinforcement learning-based quantum compiler for a superconducting processor. We demonstrate its capability of discovering novel and hardware-amenable circuits with short lengths. Our study exemplifies the codesign of the software with hardware for efficient quantum compilation.
arXiv Detail & Related papers (2024-06-18T01:49:48Z)
Extensive characterization of a family of efficient three-qubit gates at the coherence limit [0.4471952592011114]
We implement a three-qubit gate by simultaneously applying two-qubit operations. We generate two classes of entangled states, the GHZ and W states, by applying the new gate only once. We analyze the experimental and statistical errors on the fidelity of the gates and of the target states.
arXiv Detail & Related papers (2022-07-06T19:42:29Z)
High fidelity two-qubit gates on fluxoniums using a tunable coupler [47.187609203210705]
Superconducting fluxonium qubits provide a promising alternative to transmons on the path toward large-scale quantum computing. A major challenge for multi-qubit fluxonium devices is the experimental demonstration of a scalable crosstalk-free multi-qubit architecture. Here, we present a two-qubit fluxonium-based quantum processor with a tunable coupler element.
arXiv Detail & Related papers (2022-03-30T13:44:52Z)
Software mitigation of coherent two-qubit gate errors [55.878249096379804]
Two-qubit gates are important components of quantum computing. But unwanted interactions between qubits (so-called parasitic gates) can degrade the performance of quantum applications. We present two software methods to mitigate parasitic two-qubit gate errors.
arXiv Detail & Related papers (2021-11-08T17:37:27Z)
High-fidelity three-qubit iToffoli gate for fixed-frequency superconducting qubits [0.0]
We introduce a high-fidelity iToffoli gate based on two-qubit interactions, the so-called cross-resonance effect. The iToffoli gate is implemented by simultaneously applying microwave pulses to a linear chain of three qubits, revealing a process fidelity as high as 98.26(2)%. We numerically show that our gate scheme can produce additional three-qubit gates which provide more efficient gate synthesis than the Toffoli and iToffoli gates.
arXiv Detail & Related papers (2021-08-23T17:00:16Z)
Realization of arbitrary doubly-controlled quantum phase gates [62.997667081978825]
We introduce a high-fidelity gate set inspired by a proposal for near-term quantum advantage in optimization problems. By orchestrating coherent, multi-level control over three transmon qutrits, we synthesize a family of deterministic, continuous-angle quantum phase gates acting in the natural three-qubit computational basis.
arXiv Detail & Related papers (2021-08-03T17:49:09Z)
Pulse-engineered Controlled-V gate and its applications on superconducting quantum device [0.7659943611104243]
We demonstrate that, by employing OpenPulse design kit for IBM superconducting quantum devices, the controlled-V gate (CV gate) can be implemented in about half the gate time to the controlled-X gate. Using pulse-engineered CV gates enables us to implement these gates with shorter gate time and possibly better gate fidelity than the CX-based one.
arXiv Detail & Related papers (2021-02-11T16:56:56Z)
Realization of high-fidelity CZ and ZZ-free iSWAP gates with a tunable coupler [40.456646238780195]
Two-qubit gates at scale are a key requirement to realize the full promise of quantum computation and simulation. We present a systematic approach that goes beyond the dispersive approximation to exploit the engineered level structure of the coupler and optimize its control. We experimentally demonstrate CZ and $ZZ$-free iSWAP gates with two-qubit interaction fidelities of $99.76 pm 0.07$% and $99.87 pm 0.23$%, respectively.
arXiv Detail & Related papers (2020-11-02T19:09:43Z)
High-fidelity, high-scalability two-qubit gate scheme for superconducting qubits [16.01171409402694]
We experimentally demonstrate a new two-qubit gate scheme that exploits fixed-frequency qubits and a tunable coupler in a superconducting quantum circuit. The scheme requires less control lines, reduces crosstalk effect, simplifies calibration procedures, yet produces a controlled-Z gate in 30ns with a high fidelity of 99.5%. Our demonstration paves the way for large-scale implementation of high-fidelity quantum operations.
arXiv Detail & Related papers (2020-06-21T17:55:28Z)
Improving the Performance of Deep Quantum Optimization Algorithms with Continuous Gate Sets [47.00474212574662]
Variational quantum algorithms are believed to be promising for solving computationally hard problems. In this paper, we experimentally investigate the circuit-depth-dependent performance of QAOA applied to exact-cover problem instances. Our results demonstrate that the use of continuous gate sets may be a key component in extending the impact of near-term quantum computers.
arXiv Detail & Related papers (2020-05-11T17:20:51Z)

This list is automatically generated from the titles and abstracts of the papers in this site.