In this project, quantum sensors for the high-precision measurement of magnetic fields, distances, accelerations, and frequencies will be analyzed and demonstrated in selected applications. Based on the work pursued here, a long-term in-orbit demonstration of quantum sensors in satellite instruments can be achieved, which in turn could lead to an increase in the performance of satellite systems.
QSPACE – Quantum Sensors for Aerospace Applications
Accurate measurement of accelerations, gravity, frequencies, time, and magnetic fields is essential for many applications in aerospace. Sensors based on quantum systems, so-called quantum sensors, have the potential to revolutionize these measurements, as they far surpass currently used sensors in terms of accuracy and stability.
The use of quantum sensors in aerospace systems will provide a range of direct societal benefits, including:
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Improved predictions of climate change impacts through more precise measurement of changes in the Earth’s gravitational field caused by melting ice caps
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Enhanced safety in air and terrestrial transportation through accurate positioning even in the event of Galileo/GPS failures or disruptions
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New insights into planets and their formation through precise measurements of their gravitational and magnetic fields
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Improvement of GNSS systems such as Galileo or GPS through the use of highly accurate clocks and the enablement of new system architectures
The availability of quantum sensors will sustainably strengthen the aerospace industry in Baden-Württemberg.
Within the framework of QSPACE, the following research objectives are to be achieved:
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Miniaturization and demonstration of quantum sensors in the fields of inertial sensing, magnetometry, and frequency measurement for aerospace applications.
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Analysis of market potential and technology readiness of quantum sensors for use in aviation and space, and the development of a corresponding development strategy.
