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Michael G. Huber (Fed)

Huber is a member of the neutron physics group at NIST. His research focuses on neutron diffraction and interferometric techniques in order to provide insights into unresolved questions in fundamental physics. This is mainly accomplished by using perfect-crystal neutron interferometry to perform precision phase measurements on neutron-matter interactions. Being a diverse instrument, perfect-crystal neutron interferometry experiments range from quantum information science, material science, testing postulates of quantum mechanics, and searching for new short-range forces. Huber has worked on increasing the sensitivity, robustness and usability of interferometric methods. This includes the development of a far-field grating based interferometer which has applications in both fundamental and material science. The interferometer facility regularly collaborates with several universities and hosts both domestic and foreign students and post-docs.

Starting as a NIST guest researcher in 2003, Huber began work using single crystal neutron interferometry to measure nuclear scattering data for the improvement of nuclear models and effective field theories. Michael received his Ph.D. in physics from Tulane University in 2009 based on his work at NIST. He was awarded an NRC post-doc before being hired as an NIST staff scientist. Currently, he is the principle for the neutron interferometry program.

Publications

Small-Angle Scattering and Dark-Field Imaging for Validation of a New Neutron Far-Field Interferometer

Author(s)
Caitlyn M. Wolf, Peter Bajcsy, Wei-Ren Chen, Robert Dalgliesh, Michael Daugherty, Liliana de Campo, Fumiaki Funama, Lilin He, Michael Huber, David Jacobson, Paul A. Kienzle, Youngju Kim, Hubert King, Nikolai Klimov, Jacob LaManna, Fankang Li, Alexander Long, Ryan Murphy, Gergely Nagy, Sarah M. Robinson, Pushkar Sathe, Gregory N. Smith, Anna Sokolova, Sven Vogel, Erik Watkins, Yuxuan Zhang, Daniel Hussey, Kathleen Weigandt
The continued advancement of complex materials often requires a deeper understanding of the structure–function relationship across many length scales, which

Generation of Neutron Airy Beams

Author(s)
Charles W. Clark, Dmitry Pushin, Michael G. Huber, Kirill Zhernenkov, Jonathan White, Lisa DeBeer-Schmitt, David Cory, Huseyin Ekinici, Melissa Henderson, Owen Lailey, Dusan Sarenac
The Airy wave packet is a solution to the potential-free Schr¨odinger equation that exhibits remark-able properties such as self-acceleration, non-diffraction

Three-Dimensional Neutron Far-Field Tomography of a Bulk Skyrmion Lattice

Author(s)
Melissa Henderson, Benjamin Heacock, Markus Bleuel, David Cory, Colin Heikes, Michael G. Huber, Jeffery Krzywon, Olivier Nahman-Lévesque, Graeme Luke, M Pula, Dusan Sarenac, Kirill Zhernenkov, Dmitry Pushin
Magnetic skyrmions are localized non-collinear spin textures, characterized by an integer topo-logical charge. Their nanometric size and topological protection
View more Publications
Created October 9, 2019, Updated December 8, 2022
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