Title: Quantum Science: The Foundation of Modern Technology and Future Innovations
Quantum science, a fundamental aspect of modern technology, is already present in our daily lives through applications in GPS, MRI imaging, semiconductor chips, and more. This science, which can be divided into “Quantum 1.0” and “Quantum 2.0,” is crucial for understanding how these technologies function and has the potential to revolutionize future industries. Quantum 2.0, which includes entanglement, a more advanced resource for quantum computing and other applications, aims to make entanglement practical and has applications in improved sensors and communication.
Quantum science has the potential to impact various industries, including chemistry, biology, healthcare, finance, transportation, and manufacturing. Interdisciplinary collaboration is essential in this field. Practical applications of quantum mechanics already exist, underpinning technologies such as lasers, atomic clocks, and GPS. Quantum mechanics is essential for precise measurements needed to improve technology.
NIST, through its Quantum Physics Division and broader quantum information science program, supports the development and application of quantum technologies. They are involved in measurement science and have been leading in quantum mechanics since its early days. The path to making quantum technology practical involves patience, resilience, and sustained effort. NIST, along with other institutions and companies, is working towards advancing quantum technologies that can transform industries like those touched by semiconductor chips and integrated circuits in the past.
Source: https://www.nist.gov/blogs/taking-measure/gps-laser-pointers-quantum-science-all-around-us
Keywords: practical, entanglement, applications
