As we enter the Quantum Utility era, high performance, stability, and reliability are key requirements for unleashing the power of quantum computing for varied applications, from chemistry, economy, and materials to healthcare. StableQ focuses on stability issues caused by the unstable hardware noise in quantum computing. This workshop was proposed to develop an open platform to present the unstable issue to the quantum computing and computing architecture research community, report the state-of-the-art development efforts, exchange ideas and practices, and foster research collaboration to develop novel techniques to address the unstable noise issue and provide a reproducible quantum computing architecture. We aim to bring together experts and researchers from different backgrounds to explore and share their insights on this critical problem. We expect to discuss different approaches to mitigating noise, including error correction techniques, noise-reducing algorithms, and hardware improvements.

Objectives

The objective of the proposed workshop on the unstable noise of quantum computing is to address one of the most significant challenges in the development of quantum computing, which is the issue of unstable noise. The workshop aims to bring together experts and researchers from different backgrounds to explore and share their insights on this critical problem. The objective is to provide a platform to discuss different approaches to mitigating noise, including error-correction techniques, noise-reducing algorithms, and hardware improvements.

The detailed objectives are listed as follows:

• Develop a comprehensive understanding of the current state of research on unstable noise in quantum computing.
• Provide a platform for researchers and industry experts to present and discuss their latest findings and insights on mitigating unstable noise in quantum computing.
• Foster collaboration among researchers and industry experts to develop novel techniques and strategies for addressing unstable noise in quantum computing.
• Facilitate discussions on the limitations of current techniques and identify areas where further research is needed.
• Encourage the development of reproducible quantum computing systems that can effectively mitigate unstable noise.
• Provide an opportunity for attendees to network and build new collaborations in the field of quantum computing.