Flux-Trapping Fluxonium Qubit
- URL: http://arxiv.org/abs/2505.02416v1
- Date: Mon, 05 May 2025 07:22:11 GMT
- Title: Flux-Trapping Fluxonium Qubit
- Authors: Kotaro Hida, Kohei Matsuura, Shu Watanabe, Yasunobu Nakamura,
- Abstract summary: In pursuit of superconducting quantum computing, fluxonium qubits have recently garnered attention for their large anharmonicity and high coherence at the sweet spot.<n>To achieve high performance at its sweet spot, each qubit requires a DC bias line.<n>We propose a flux-trapping fluxonium qubit, which, by leveraging fluxoid quantization, enables the optimal phase biasing without using external magnetic flux control.
- Score: 2.3207473918427386
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: In pursuit of superconducting quantum computing, fluxonium qubits have recently garnered attention for their large anharmonicity and high coherence at the sweet spot. Towards the large-scale integration of fluxonium qubits, a major obstacle is the need for precise external magnetic flux bias: To achieve high performance at its sweet spot, each qubit requires a DC bias line. However, such lines inductively coupled to the qubits bring in additional wiring overhead, crosstalk, heating, and decoherence, necessitating measures for mitigating the problems. In this work, we propose a flux-trapping fluxonium qubit, which, by leveraging fluxoid quantization, enables the optimal phase biasing without using external magnetic flux control at the operating temperature. We introduce the design and working principle, and demonstrate the phase biasing achieved through fluxoid quantization.
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