Quantum-Enabled Materials for Next-Gen Sensors and Computing
Quantum-Enabled Materials for Next-Gen Sensors and Computing are at the frontier of scientific and technological innovation, unlocking unprecedented capabilities in sensing, information processing, and quantum communication. As quantum technologies transition from laboratory research to real-world applications, advanced material breakthroughs are becoming the driving force behind miniaturized, ultra-sensitive, and highly efficient systems.
At the Global Conference on Materials Science and Advanced Manufacturing (MSAM – 2026), this session will explore how cutting-edge materials are shaping the future of quantum devices and infrastructures.
We invite submissions and expert talks on:
• Topological Quantum Materials: Exploring exotic states of matter that enable fault-tolerant quantum computation and low-dissipation electronics.
• Superconducting Materials for Quantum Circuits: Breakthroughs in superconductors for scalable quantum computing and sensing.
• 2D Quantum Materials: Advances in atomically thin materials like graphene, TMDs, and their role in quantum transport and spintronics.
• Quantum Dots and Single-Photon Sources: Engineering nanostructures for quantum communication, encryption, and precision sensing.
• Defects and Color Centers in Wide Bandgap Materials: Utilizing engineered defects for quantum sensing and information storage.
• Quantum Metamaterials: Artificially structured materials designed for quantum photonics and exotic light-matter interactions.
• Spintronic and Magnonic Materials: Pioneering materials that use electron spin for next-generation quantum memory and logic devices.
• Quantum Sensors and Detectors: Materials advancements enabling ultra-sensitive detection in medical, environmental, and navigation applications.
• Hybrid Quantum Systems: Integrating quantum materials with classical systems for multifunctional device platforms.
• Coherence and Noise Mitigation in Quantum Materials: Strategies to improve stability, coherence times, and performance at practical scales.
• Cryogenic Materials for Quantum Systems: Innovations enabling reliable operation of quantum devices at ultra-low temperatures.
• Quantum Simulation for Materials Discovery: Using quantum computing to accelerate the design of next-gen materials.
• Energy Applications of Quantum Materials: Emerging roles in energy conversion, storage, and harvesting technologies.
• Fabrication and Scale-up Challenges: Addressing practical challenges in producing high-quality, reproducible quantum-enabled materials.
• Future Outlook: How quantum materials will impact AI, aerospace, healthcare, defense, and beyond.
This session is a must-attend for researchers, engineers, and industry leaders driving the material innovations behind the quantum revolution.
Join us at MSAM – 2026 and be part of the future of quantum materials and technologies!