Humboldt Fellow Alexander Gray comes to HZB

Alexander Gray (here in his lab at Temple University, Philadelphia, USA) will strengthen his collaboration with the team of Florian Kronast at BESSY II.

Alexander Gray (here in his lab at Temple University, Philadelphia, USA) will strengthen his collaboration with the team of Florian Kronast at BESSY II. © Privat

Alexander Gray from Temple University in Philadelphia, USA, is working with HZB physicist Florian Kronast to investigate novel 2D quantum materials at BESSY II. With the fellowship from the Alexander von Humboldt Foundation, he can now deepen this cooperation. At BESSY II, he wants to further develop depth-resolved X-ray microscopic and spectroscopic methods in order to investigate 2D quantum materials and devices for new information technologies even more thoroughly.

 

Topological insulators and Weyl semimetals are among the most exciting classes of materials for quantum devices. They are characterised by the fact that they have different electronic and magnetic  properties at the surfaces and interfaces than in the volume.

Alexander Gray is a well-known expert in this field and frequently comes to BESSY II for short measurement periods, where he cooperates with Florian Kronast. As a Fellow of the Alexander von Humboldt Foundation, the American physicist can now finance regular guest stays at HZB with Florian Kronast's team and at Forschungszentrum Jülich with Claus Schneider's team. "The Humboldt Fellowship gives us more time, so we can investigate and discuss in more detail how the interplay between surface, interface and bulk properties in quantum materials leads to novel phenomena that enable device applications," he says.  

Gray leads a team at Temple University in Philadelphia and also plans to send his students to BESSY II. "We want to develop new techniques to study the electronic and magnetic properties of 2D quantum materials and quantum devices in more detail," he outlines his goals. At BESSY II, Gray will primarily develop depth-resolved standing-wave photoemission microscopy further for this purpose. Kronast, Gray, and his former doctoral advisor Chuck Fadley have already combined this method with excitation by standing X-ray waves to enable depth resolution (SW-PEEM).

From mid-August, Alexander Gray is planning his first stay at BESSY II. He is not only looking forward to the measurements and many discussions, but also to the typical Berlin atmosphere: "The people are really open and friendly, and I have never experienced the famous "Berlin snout". I think if I do one day, I might deserve it." With this attitude, full of humor, his stay in Berlin will be a huge success in every aspect.

arö

You might also be interested in

  • Rhombohedral graphite as a model for quantum magnetism
    Science Highlight
    27.09.2022
    Rhombohedral graphite as a model for quantum magnetism
    Graphene is an extremely exciting material. Now a graphene variant shows another talent: rhombohedral graphite made of several layers slightly offset from each other could enlighten the hidden physics in quantum magnets.
  • 40 years of research with synchrotron light in Berlin
    News
    14.09.2022
    40 years of research with synchrotron light in Berlin
    Press release _ Berlin, 14 September: For decades, science in Berlin has been an important driver of innovation and progress. Creative, talented people from all over the world come together here and develop new ideas from which we all benefit as a society. Many discoveries – from fundamental insights to marketable products – are made by doing research with synchrotron light. Researchers have had access to this intense light in Berlin for 40 years. It inspires many scientific disciplines and is an advantage for Germany.

  • New road towards spin-polarised currents
    Science Highlight
    08.09.2022
    New road towards spin-polarised currents
    The transition metal dichalcogenide (TMD) series are a family of promising candidate materials for spintronics. A study at lightsource BESSY II has unveiled that in one of those materials even simple linear polarised light is sufficient to selectively manipulate spins of different orientations. This result provides an entirely new route for the generation of spin-polarised currents and is a milestone for the development of spintronic and opto-spintronic devices.