The paper introduces an extensible 2D fluxonium qubit architecture using low-shunt-capacitance tunable couplers realized as quarton or fluxonium circuits to enable strong tunable interactions and multiple connections while supporting fast high-fidelity gates.
Long-range tunable coupler for modular fluxonium quantum processors
2 Pith papers cite this work. Polarity classification is still indexing.
abstract
The path toward practical superconducting quantum processors requires the integration of a large number of high-performance qubits. Modular architectures could offer a way to address the scaling limitations of monolithic designs by partitioning a large quantum processor into physically separated modules, or chiplets, linked through long-range interconnects. In this context, although fluxonium qubits have emerged as a compelling platform for quantum computing due to their long coherence times and high-fidelity gates, existing coupling schemes remain restricted to qubits in close proximity on a single chip. This limitation inherently precludes the long-range interconnects essential for modular integration. In this work, we propose a long-range tunable coupler designed to interconnect fluxonium qubits separated by more than one centimeter, thereby supporting the realization of modular fluxonium quantum processors. Under realistic assumptions, the proposed coupler has the potential to achieve inter-module two-qubit gate performance, specifically sub-100-ns gates with intrinsic errors below $10^{-4}$, comparable to that of intra-module (intra-chiplet) gates, while enabling modular integration with low quantum crosstalk, a key requirement for scalable systems. We further discuss the integration of this coupler into modular fluxonium lattices and explore its feasibility for achieving the higher connectivity and longer coupling range required for complex quantum error correction codes. This work could contribute to the development of large-scale fluxonium quantum processors by bridging their demonstrated potential with modular scalability.
fields
quant-ph 2years
2026 2verdicts
UNVERDICTED 2representative citing papers
A system-level design methodology for scalable fluxonium processors with double-transmon couplers that supports high-fidelity gates, fast reset, and dispersive readout through frequency partitioning under realistic constraints.
citing papers explorer
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Extensible Fluxonium Architecture Using Tunable Couplers with Low Shunt Capacitance
The paper introduces an extensible 2D fluxonium qubit architecture using low-shunt-capacitance tunable couplers realized as quarton or fluxonium circuits to enable strong tunable interactions and multiple connections while supporting fast high-fidelity gates.
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System-Level Design of Scalable Fluxonium Quantum Processors with Double-Transmon Couplers
A system-level design methodology for scalable fluxonium processors with double-transmon couplers that supports high-fidelity gates, fast reset, and dispersive readout through frequency partitioning under realistic constraints.