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Scattering And Absorption of Light in Planetary Regoliths
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A magnon scattering platform.

Tony X Zhou1,2, Joris J Carmiggelt3,4, Lisa M Gächter3,5

  • 1Department of Physics, Harvard University, Cambridge, MA 02138; gztony1227@gmail.com yacoby@physics.harvard.edu.

Proceedings of the National Academy of Sciences of the United States of America
|June 16, 2021
PubMed
Summary
This summary is machine-generated.

This study introduces a novel table-top platform for magnetic scattering experiments using magnonic excitations. The system enables detailed imaging of magnetic properties on mesoscopic scales, advancing the study of complex materials.

Keywords:
condensed matter physicsmagnetometrymagnonquantum sensingscattering

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Area of Science:

  • Condensed Matter Physics
  • Materials Science
  • Quantum Sensing

Background:

  • Scattering experiments have historically been pivotal in scientific discovery, from nuclear physics to molecular biology.
  • Existing scattering techniques often lack the resolution or versatility to probe magnetic properties at mesoscopic scales.
  • The need for advanced platforms to study complex magnetic phenomena in materials is increasingly apparent.

Purpose of the Study:

  • To demonstrate a novel two-dimensional table-top scattering platform for investigating material magnetic properties.
  • To explore magnetic responses on mesoscopic length scales using coherent magnonic excitations.
  • To enable spatial determination of both amplitude and phase of scattered waves for detailed analysis.

Main Methods:

  • Generation of long-lived, coherent magnonic excitations in yttrium iron garnet thin films.
  • Scattering of magnons off a magnetic target deposited on the yttrium iron garnet surface.
  • Detection and imaging of scattered waves using a scanning nitrogen vacancy center magnetometer, enabling subwavelength resolution.

Main Results:

  • Successful demonstration of a table-top platform capable of imaging magnetic properties with high resolution.
  • Spatial mapping of scattered wave amplitude and phase, allowing for reconstruction of the target scattering potential.
  • Observation of unusual magnetic response features, including edge suppression and perpendicular gradients, consistent with theoretical predictions.

Conclusions:

  • The developed platform provides a versatile tool for studying magnetic phenomena across various length scales and environments.
  • Magnon scattering experiments are established as a powerful method for investigating correlated many-body systems.
  • The ability to reconstruct scattering potentials opens new avenues for materials characterization and fundamental physics research.