Juq016 Link __top__

For anyone building or researching quantum hardware in 2026 and beyond, the JUQ016 Link represents a toward scalable, fault‑tolerant quantum computation.

: Similar codes (e.g., YOKE G-100 Connecting Links ) exist for heavy-duty lifting hardware, though they typically use different prefixes like "X-015-16". Overview of JUQ-278 and JUQ-016 | PDF - Scribd juq016 link

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| Partner | Contribution | |---------|--------------| | | Early adopter; integrated JUQ016 into the IBM Quantum System Two for inter‑module QEC. | | Rigetti | Co‑development of the cryogenic driver ASIC, leveraging their 7 nm RF process. | | Google Quantum AI | Benchmarked JUQ016 against proprietary interconnects; reported 2× speed‑up in Sycamore‑style experiments. | | Intel | Provided the SiN waveguide platform for the optical mode and contributed the Silicon‑Photonic Integration Kit (SPIK). | | University of Sydney | Conducted independent latency measurement campaign; results published in Nature Quantum Electronics (2026). | For official documentation and professional tools, it is