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A New Way of Seeing the Nano World

How can electron microscopy be combined with the measurement of magnetic spins? Philipp Haslinger is developing a new type of measurement technique, and has been awarded an ERC Consolidator Grant to pursue it.

Philipp Haslinger with green background

© P. Haslinger / TU Wien

Philipp Haslinger

Modern electron microscopes achieve remarkable resolutions and can image details on the atomic scale. Yet they are not well suited for sensitive materials such as biological samples: when fragile molecules are bombarded with high-energy electron beams, such materials are quickly destroyed.

Philipp Haslinger works in the field of quantum and matter-wave optics. In recent years, his research has led him to a radically new way of extending the capabilities of electron microscopy. His idea is to use electrons as “miniature magnetic sensors” that can probe the quantum properties of a sample in a gentle, non-destructive manner, similar to the way MRI scans reveal the interior of the human body. To develop this technology further, he has now been awarded a Consolidator Grant from the European Research Council (ERC).

Electron Beams and Electron Spins

“We combine two technologies that have so far been regarded as completely separate,” says Philipp Haslinger. “On the one hand electron microscopy, and on the other hand magnetic resonance spectroscopy.” The two methods offer very different strengths: electron microscopy achieves nanometer-scale resolution, while magnetic resonance has lower spatial resolution but excels at distinguishing between different quantum states of matter with extraordinary sensitivity.

In a conventional electron microscope, electrons essentially play the same role as light in an optical microscope: the sample is ‘illuminated’ with electrons, which are then scattered and detected to create an image.

Haslinger’s team, however, takes a quantum approach. According to quantum physics, electrons behave like waves, similar to water waves reflecting from the edge of a pool and interfering with themselves. By measuring these interference patterns, one can infer how the electron interacted with the matter it passed by. “The particles in the material possess quantum spins, an intrinsic angular momentum that generates a tiny magnetic field,” explains Haslinger. “We can measure this magnetic field using electrons, and we can do so a thousand times better than before.”

The measurement proceeds in two steps. First, the sample is excited: microwave radiation is used to coherently manipulate the magnetic spins in a very gentle way. Then the electron beam is sent in to ‘pick up’ the spin information from the sample surface.“Simulations show that this technique has tremendous potential,” says Haslinger. “We are very confident that in the coming years we will be able to produce extremely high-precision images with this new method.”

Philipp Haslinger

Philipp Haslinger studied physics and mathematics at the University of Vienna and completed his PhD in the group of Prof. Markus Arndt on matter-wave interferometry. After research stays at the University of California, Berkeley, and postdoctoral positions in Vienna and the United States, he increasingly focused on atom interferometry and the search for dark energy, correlated electron-photon pairs, and quantum electron microscopy. His work has received numerous awards, including the START Prize and the Young Scientist Prize of the European Physical Society, as well as major research grants from the FWF and FFG. With his ERC Consolidator Grant, he will now continue to develop and expand his research group at the Atominstitut and the University Service Center for Transmission Electron Microscopy at TU Wien.

 

Contact:

Prof. Philipp Haslinger
Institute of Atomic and Subatomic Physics
Technische Universität Wien
+43 1 58801 141869
philipp.haslinger@tuwien.ac.at 

Text: Florian Aigner