The recent collaboration between Germany’s Forschungszentrum Jülich and Korea’s IBS Center for Quantum Nanoscience (QNS) has led to a groundbreaking development in quantum sensor technology. Scientists have long been striving to create a tool capable of detecting minute magnetic fields at the atomic-length scale, similar to an MRI for quantum materials.

One of the key innovations in this research is the utilization of single-molecule fabrication expertise from the Jülich group combined with the cutting-edge instrumentation and methodological know-how at QNS. Unlike traditional quantum sensors that rely on crystal lattice defects, the new atomic-scale quantum sensor uses a single molecule attached to the tip of a scanning tunneling microscope. This innovative approach allows for a much higher degree of spatial resolution, bringing the sensor within a few atomic distances of the object being observed.

Dr. Taner Esat, lead author of the Jülich team, expressed his excitement about the potential applications of the new quantum sensor. By providing images of materials with MRI-like richness and setting a new standard for spatial resolution in quantum sensors, this technology opens up transformative avenues for engineering quantum materials, designing catalysts, and exploring the fundamental quantum behavior of molecular systems.

The quantum sensor developed in this research has the remarkable ability to detect changes in magnetic and electric fields with a spatial resolution on the order of a tenth of an ångström. Its energy resolution allows for unprecedented detail in observing atomic properties, paving the way for a deeper understanding of materials at their most fundamental level.

The development of this atomic-scale quantum sensor represents a significant milestone in the field of quantum technology. Its impact is expected to extend across various scientific disciplines, from engineering quantum materials and devices to exploring the quantum behavior of molecular systems in biochemistry. As the technology continues to evolve, the potential for manipulating matter at the atomic level is truly infinite.

The collaboration between the research teams from Forschungszentrum Jülich and the IBS Center for Quantum Nanoscience has resulted in a transformative advancement in quantum sensing technology. The development of the world’s first atomic-scale quantum sensor opens up new possibilities for scientific exploration and discovery, with far-reaching implications for the field of quantum materials research. This innovative approach to quantum sensing has the potential to revolutionize our understanding of materials at the atomic level and pave the way for exciting new developments in quantum technology.

Physics

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