The INGENIOUS project was conceived to overcome a long-standing barrier in quantum science—the reliable detection of individual microwave photons. Unlike optical photon detectors, which have revolutionized many fields, the low energy of microwave photons renders conventional detection methods ineffective. By leveraging superconducting quantum circuits and innovative dissipation engineering, our approach transforms a challenging problem into an opportunity for breakthrough. Over the past two years, we have developed a high-performance microwave photon detector that achieves robust, continuous photon counting. Through systematic optimization of the quantum circuit, we dramatically reduced dark count rates and significantly boosted detection efficiency, thereby accelerating measurement speeds by a factor of 100. A central element of our strategy is modularity: the detector is decoupled from the system under study via standard microwave components operating at millikelvin temperatures, allowing independent optimization of both the detection unit and the experimental apparatus.
This breakthrough technology is enabling transformative applications that extend far beyond the detector itself. In magnetic resonance, our technology empowers the detection of the faint microwave fluorescence emitted by individual electron or nuclear spins. This capability heralds a new era in quantum sensing, offering unprecedented insight into the magnetic properties of molecular systems and materials at the nanoscale. By capturing these subtle signals, we can probe the structure and dynamics of individual atoms with remarkable precision, paving the way for advanced quantum computing where high-coherence spin systems are interfaced with superconducting qubits. In such hybrid architectures, individual spins serve as robust quantum memories and processing units, forming the cornerstone of scalable quantum computing platforms with high-fidelity operations and error-corrected quantum state manipulation. Moreover, our detector’s versatility extends to high-energy physics, where its enhanced sensitivity is now being explored for the search for dark matter axions. By resolving extremely weak microwave signals that could indicate axion interactions in strong magnetic fields, our technology holds the promise of significantly reducing search times and expanding the accessible parameter space. Together, these applications underscore the true impact of the INGENIOUS project—a practical, high-performance detector that is not only advancing the frontiers of microwave photon counting but also serving as a critical enabling technology for next-generation quantum information processing, magnetic resonance sensing, and fundamental physics research.