## Thesis Develop a quantum sensing platform utilizing an integrated operating system, advanced noise mitigation techniques, and comprehensive benchmarking. This platform will support various quantum sensing modalities (e.g., magnetometers, accelerometers, gyroscopes) for applications in environmental monitoring, infrastructure assessment, and industrial optimization. By leveraging both ultracold and warm quantum technologies, the platform will offer unmatched sensitivity and precision, addressing critical challenges in multiple industries. ### 1. State of Quantum Technology, TRLs, and Timelines Quantum technologies are evolving rapidly, with advancements in quantum computing, networking, and sensing. Technology Readiness Levels (TRLs) vary, but many quantum sensors are reaching TRL 5-7, indicating maturity and near-market readiness. Commercialization is expected to accelerate within the next 3-5 years, particularly for practical applications using warm quantum sensors. ### 2. Applications & Use Cases **Industry Verticals and Use Cases:** - **Environmental Monitoring:** Precise detection of greenhouse gases and pollutants using quantum gas sensors. - **Infrastructure Assessment:** Gravity mapping sensors for sinkhole detection and structural integrity checks. - **Mining and Resource Exploration:** Quantum gravimeters for detecting mineral deposits and disused mine shafts. - **Navigation and Transportation:** Quantum gyroscopes for unspoofable navigation aids. - **Security and Defense:** Quantum radars offering enhanced sensitivity and resistance to jamming. **Low-Hanging Fruits:** - Emissions monitoring for regulatory compliance. - Early detection of sinkholes in urban planning. Ref: [[Quantum Sensing 101]] | [[Quantum Sensing Benchmarks]]