Integration of graphene-based superconducting quantum circuits in 3D cavity
- URL: http://arxiv.org/abs/2312.03985v2
- Date: Sun, 02 Mar 2025 22:45:37 GMT
- Title: Integration of graphene-based superconducting quantum circuits in 3D cavity
- Authors: Kuei-Lin Chiu, Youyi Chang, Avishma J. Lasrado, Cheng-Han Lo, Yung-Hsiang Chen, Tao-Yi Hsu, Yen-Chih Chen, Yi-Chen Tsai, Samina, Yen-Hsiang Lin, Chung-Ting Ke,
- Abstract summary: We build the first 3D cavity-compatible superconducting quantum circuit based on 2D materials.<n>A graphene superconducting quantum interference device (SQUID) is shunted by a capacitor that is accessible by both DC and microwave probes.<n>In addition, we extracted the symmetry information of the SQUIDs based on DC analysis, and correlated this with the flux-modulated cavity frequency observed in microwave measurements.
- Score: 0.0
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Integrating 2D materials into circuit quantum electrodynamics (c-QED) devices is an emerging filed in recent years. This integration not only facilitates the exploration of potential applications in quantum information processing but also enables the study of material's fundamental properties using microwave techniques. While most studies employ 2D coplanar architectures with scalability potential, 3D cavity based c-QED devices, due to their simpler design, offer the advantage of a quicker turnaround to probe the composite Josephson junctions (JJs). Here, we construct the first flux-tunable, 3D cavity-compatible superconducting quantum circuit based on 2D materials, featuring a graphene superconducting quantum interference device (SQUID) shunted by a capacitor that is accessible by both DC and microwave probes. We have shown how flux-modulated cavity frequency can be linked to the SQUID critical current under the influence of Fraunhofer pattern. In addition, we extracted the symmetry information of the SQUIDs based on DC analysis, and correlated this with the flux-modulated cavity frequency observed in microwave measurements. Our platform can extend to topological materials, holding the prospect of establishing valid topological JJs with DC probe while allowing fast microwave probe to avoid quasiparticle poisoning.
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