The 20th century bequeathed a scientific and technological legacy marked by milestones like quantum mechanics and groundbreaking space missions. Both pursuits have paved new paths for expanding our understanding of nature, standing as true benchmarks of modern science. Quantum theory and space science constitute foundational elements of a robust research framework, propelling the exploration of the frontiers of modern physics through experimental tests conducted in space, offering unique working conditions.
Space-based generation of entangled photons holds the potential to establish global quantum communication networks, conduct long-distance tests of quantum theory, and investigate the intricate interplay between relativity and quantum entanglement.
Extended free-fall durations provide opportunities for high-precision tests of general relativity and examinations of the equivalence principle for quantum systems.
Leveraging microgravity, deep space’s high vacuum, and low temperatures offer the prospect of studying deviations from standard quantum theory for high-mass test particles. Spaceborne experiments in metrology and sensing are poised to elevate the precision of clocks, mass detectors, and transducers, pushing towards the engineering of innovative quantum technologies.
“Quantum Technologies in Space (QTSpace)” aspires to create this dynamic framework, presenting an exciting opportunity to deepen our comprehension of fundamental physics mechanisms in an entirely novel context. QTSpace embodies a visionary initiative for advancing our understanding of the universe’s intricacies.
Link: www.qtspace.eu