Analysis of a 3D Integrated Superconducting Quantum Chip Structure
- URL: http://arxiv.org/abs/2505.02263v1
- Date: Sun, 04 May 2025 21:34:04 GMT
- Title: Analysis of a 3D Integrated Superconducting Quantum Chip Structure
- Authors: James Saslow, Hiu Yung Wong,
- Abstract summary: This work presents a combined analytical and simulation-based study of a 3D-integrated quantum chip architecture.<n>We model a flip-chip-inspired structure by stacking two superconducting qubits fabricated on separate high-resistivity silicon substrates.<n>We evaluate key quantum metrics such as eigenfrequencies, Q-factors, decoherence times, anharmonicity, cross-Kerr, participation ratios, and qubit coupling energy.
- Score: 0.0
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: This work presents a combined analytical and simulation-based study of a 3D-integrated quantum chip architecture. We model a flip-chip-inspired structure by stacking two superconducting qubits fabricated on separate high-resistivity silicon substrates through a dielectric interlayer. Utilizing \emph{rigorous} Ansys High-Frequency Structure Simulator (HFSS) simulations and analytical models from microwave engineering and quantum theory, we evaluate key quantum metrics such as eigenfrequencies, Q-factors, decoherence times, anharmonicity, cross-Kerr, participation ratios, and qubit coupling energy to describe the performance of the quantum device as a function of integration parameters. The integration parameters include the thickness and the quality of the dielectric interlayer. For detuned qubits, these metrics remain mostly invariant with respect to the substrate separation. However, introducing dielectric interlayer loss decreases the qubit quality factor, which consequentially degrades the relaxation time of the qubit. It is found that for the structure studied in this work, the stacked chip distance can be as small as $0.5 \text{mm}$. These findings support the viability of 3D quantum integration as a scalable alternative to planar architectures, while identifying key limitations in qubit coherence preservation due to lossy interlayer materials.
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