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Related Concept Videos

Standing Waves in a Cavity01:28

Standing Waves in a Cavity

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A household microwave and lasers are examples of standing electromagnetic waves in a cavity. When two conducting metal plates are placed parallel at the nodal planes, it creates a cavity where standing waves are formed. The cavity between the two planes is analogous to a stretched string held at the points x = 0 and x = L. Here, the distance 'L' between the two planes must be an integer multiple of half of the wavelength. The wavelengths that satisfy this condition are given by:
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When a wave propagates from one medium to another, part of it may get reflected in the first medium, and part of it may get transmitted to the second medium. In such a case, the interface of the two mediums can be considered as a boundary that is neither fixed nor free.
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Fabrication And Characterization Of Photonic Crystal Slow Light Waveguides And Cavities
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A soft-clamped topological waveguide for phonons.

Xiang Xi1,2, Ilia Chernobrovkin3,4, Jan Košata5,6

  • 1Niels Bohr Institute, University of Copenhagen, Copenhagen, Denmark. xiang.xi@nbi.ku.dk.

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|June 4, 2025
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Summary
This summary is machine-generated.

Researchers developed ultralow-loss phononic waveguides using valley-Hall topological insulators. This breakthrough significantly reduces phonon loss, enabling robust, topologically protected transport on-chip for advanced quantum technologies.

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Area of Science:

  • Condensed Matter Physics
  • Topological Materials
  • Phononics

Background:

  • Topological insulators, initially discovered for electrons, have been extended to bosonic systems like photons and phonons.
  • Topological protection offers theoretical backscattering immunity for wave propagation in artificial lattices.
  • Previous phononic waveguides suffered from high propagation losses (dB cm⁻¹), limiting practical applications.

Purpose of the Study:

  • To engineer on-chip phononic waveguides with drastically reduced dissipation losses.
  • To investigate and quantify the backscattering protection in topological phononic systems.
  • To create a clean bosonic system for studying topological protection and non-Hermitian physics.

Main Methods:

  • Combined advanced dissipation engineering, specifically soft clamping, with valley-Hall topological insulator concepts for phonons.
  • Fabrication of on-chip phononic waveguides.
  • Utilized high-resolution ultrasound spectroscopy to measure propagation losses and backscattering.

Main Results:

  • Achieved unprecedentedly low phononic propagation losses of 3 dB km⁻¹ at room temperature, orders of magnitude lower than previous devices.
  • Demonstrated highly effective backscattering protection, with phonons navigating a 120° bend with 99.99% probability.
  • Quantified minimal phonon loss, with less than one in a million lost during propagation.

Conclusions:

  • The developed phononic waveguides exhibit ultralow loss and robust topological protection, overcoming previous limitations.
  • This work paves the way for new research in low-loss phononic devices and topological physics.
  • Provides a clean platform for exploring topological protection and non-Hermitian phenomena in bosonic systems.