Featured Image: Optically pumped magnetometers (OPMs) are characterized by their extremely high magnetic field sensitivity and are therefore able to detect the smallest material damage. © Fraunhofer IAF
Press release Fraunhofer IAF, 23 Jan 2024
Quantum magnetometers are able to detect and visualize the tiniest damage in ferromagnetic materials. In aerospace technology or the automotive industry, they can help to significantly increase the resilience and safety of systems and materials. This conclusion was reached by researchers from the recently completed Fraunhofer lighthouse project QMag. They also investigated the use of quantum magnetometers in biomedicine, flow measurement and chip production.
Structural defects such as cracks, precipitations or other irregularities in metallic materials lead to local changes in the magnetic field, which can be tested non-destructively using magnetometers. Quantum magnetometers are much more sensitive than conventional technologies and can detect even tiny magnetic changes in materials. “In automotive and aerospace engineering, it is essential to ensure the reliability and durability of materials, but the technologies used to date are either too large or not available to industry,” says Prof. Dr. Rüdiger Quay, project manager of QMag and director of the Fraunhofer Institute for Applied Solid State Physics IAF.
In the project “Quantum Magnetometry,” or QMag for short, Fraunhofer researchers have investigated and further developed quantum sensors for specific industrial applications. They worked with two complementary approaches: On the one hand, they used optically pumped magnetometers (OPMs), which are characterized by their extremely high magnetic field sensitivity, and on the other hand, they used imaging quantum magnetometers based on nitrogen vacancy (NV) centers in diamond with extremely high spatial resolution.
Both technologies work at room temperature and are suitable for industrial applications. The research results show that the quantum magnetometers detect changes in the magnetic field of the samples even when the material fatigue is not yet visible. The researchers used OPMs to measure the changes in the magnetic field of ferromagnetic material samples while they were subjected to cyclic fatigue. They have thus demonstrated that quantum magnetometers detect the smallest material defects much earlier than conventional technologies. It was also possible to shorten the measurement time, which is very important for use in industrial processes such as component testing.
In material testing, OPMs and NV magnetometers can be used in complementary ways: While OPMs provide a dynamic signal from the entire sample, NV magnetometry can be used to measure the magnetic properties of individual damage on the micro- and nanoscale in detail. “In material testing, quantum magnetometers can help to estimate the failure of ferromagnetic components before the materials exhibit recognizable cracks. This plays a particularly important role in safety-critical components,” says Dr. Simon Philipp, researcher at the Fraunhofer Institute for Mechanics of Materials IWM.
Further applications in biomedicine, flow measurement and the chip industry
The researchers have also succeeded in developing a new NV magnetometer that leads to faster results in material testing and even enables further applications: the wide-field magnetometer measures magnetic fields over a large sample area in a very short time and is therefore suitable for rapid measurements in industrial applications. “The wide-field magnetometer can be used for the characterization and optimization of ferromagnetic materials, but it is also very well suited for applications in biomedicine and medical technology. Organic samples can be examined non-destructively and with imaging,” says Niklas Mathes, researcher at Fraunhofer IAF.
The researchers achieved a further success with the use of OPMs in flow measurement: they have developed a completely new method for measuring the flow velocities of liquids in a pipe based on OPMs. Magnetometric flow measurement is a non-contact method that can be applied to a wide range of media and is suitable for use in process control. This method represents a significant advance, as previous methods of flow measurement are usually invasive.
The project team also investigated the use of quantum magnetometers in micro- and nanoelectronics and chip production and identified enormous potential: In quality control, quantum magnetometers can be used to measure electrical circuits and immediately detect faulty transistors, for example.
Testing facilities for the industry
In order to make the research results accessible to industry and to test the technologies developed for specific applications, two testing facilities were set up as part of the project. A magnetically shielded room has been installed at the Fraunhofer Institute for Physical Measurement Techniques IPM, which can be used for test measurements. “The magnetic environment in the testing facility has a residual field of less than 5 nanotesla and offers very high noise suppression. This allows us to measure even the smallest magnetic fields generated by brain waves. We make this environment available to industry for measurement services,” explains Dr. Peter Koss, researcher at Fraunhofer IPM.
In order to facilitate the transfer of quantum magnetometers to industry, a further testing facility was set up at Fraunhofer IAF, which contains several NV magnetometers. It enables interested companies, especially SMEs and start-ups, to evaluate the benefits and potential of quantum magnetometers for their specific requirements.
About the QMag project
In the Fraunhofer lighthouse project “Quantum Magnetometry,” five German Fraunhofer Institutes of Fraunhofer-Gesellschaft and the British Fraunhofer CAP have joined forces to bring quantum sensors from the laboratory to industry. The project ran from 2019 to 2023 and was funded with 10 million euros in equal parts by the Fraunhofer-Gesellschaft and the Baden-Württemberg Ministry of Economic Affairs, Labor and Tourism.
The project consortium consisted of:
- Fraunhofer Institute for Applied Solid State Physics IAF
- Fraunhofer Institute for Physical Measurement Techniques IPM
- Fraunhofer Institute for Mechanics of Materials IWM
- Fraunhofer Institute for Integrated Systems and Device Technology IISB
- Fraunhofer Institute for Microtechnology and Microsystems IMM
- Fraunhofer Centre for Applied Photonics CAP
The consortium received academic advice from Prof. Dr. Jörg Wrachtrup from the University of Stuttgart and Prof. Dr. Svenja Knappe from the University of Colorado Boulder.