Jove
Visualize
Contact Us
JoVE
x logofacebook logolinkedin logoyoutube logo
ABOUT JoVE
OverviewLeadershipBlogJoVE Help Center
AUTHORS
Publishing ProcessEditorial BoardScope & PoliciesPeer ReviewFAQSubmit
LIBRARIANS
TestimonialsSubscriptionsAccessResourcesLibrary Advisory BoardFAQ
RESEARCH
JoVE JournalMethods CollectionsJoVE Encyclopedia of ExperimentsArchive
EDUCATION
JoVE CoreJoVE BusinessJoVE Science EducationJoVE Lab ManualFaculty Resource CenterFaculty Site
Terms & Conditions of Use
Privacy Policy
Policies

Related Concept Videos

Standing Waves in a Cavity01:28

Standing Waves in a Cavity

1.3K
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:
1.3K
Poisson's And Laplace's Equation01:25

Poisson's And Laplace's Equation

3.9K
The electric potential of the system can be calculated by relating it to the electric charge densities that give rise to the electric potential. The differential form of Gauss's law expresses the electric field's divergence in terms of the electric charge density.
3.9K
Electrostatic Boundary Conditions in Dielectrics01:27

Electrostatic Boundary Conditions in Dielectrics

1.6K
When an electric field passes from one homogeneous medium to another, crossing the boundary between the two mediums imparts a discontinuity in the electric field. This results in electrostatic boundary conditions that depend on the type of mediums the field propagates through.
Consider a case where both the mediums across a boundary are two different dielectric materials. Recall that the electric field and electric displacement are proportional and related through the material's permittivity....
1.6K
Boundary Conditions for Current Density01:25

Boundary Conditions for Current Density

1.2K
Current density becomes discontinuous across an interface of materials with different electrical conductivities. The normal component of the current density is continuous across the boundary.
1.2K
Electromagnetic Fields01:30

Electromagnetic Fields

2.5K
Electric fields generated by static charges, often referred to as electrostatic fields, are characteristically different from electric fields created by time-varying magnetic fields. While the former is a conservative field, implying that no net work is done on a test charge if it goes around in a complete loop in the field, the latter is, by definition, not a conservative field; net work is done, and it is proportional to the rate of change of magnetic flux.
However, the observation of...
2.5K
Inductance: Solid Cylindrical Conductor01:24

Inductance: Solid Cylindrical Conductor

683
To calculate the inductance of a solid cylindrical conductor, consider a 1-meter section of a non-magnetic, current-carrying conductor with radius r. Disregarding end effects and assuming uniform current density, Ampere's law helps determine the magnetic field inside the conductor. This law states that the magnetic field intensity H is concentric and constant within the conductor.
Given the uniform current distribution, the magnetic field Hx and flux density Bx inside the conductor are...
683

You might also read

Related Articles

Articles linked to this work by shared authors, journal, and citation graph.

Sort by
Same author

Uniaxial spin texture in a superconducting electron gas revealed by exchange interactions.

Science advances·2026
Same author

Correction to "Tuning Kinetic Inductance with Doping in Superconducting Electron Gases at the KTaO<sub>3</sub> (111) Interface".

Nano letters·2025
Same author

Tuning Kinetic Inductance with Doping in Superconducting Electron Gases at the KTaO<sub>3</sub> (111) Interface.

Nano letters·2025
Same author

Rippled metamaterials with scale-dependent tailorable elasticity.

Proceedings of the National Academy of Sciences of the United States of America·2025
Same author

Single-Electron Qubits Based on Quantum Ring States on Solid Neon Surface.

Physical review letters·2024
Same author

Slow-Wave Hybrid Magnonics.

Physical review letters·2024
Same journal

Erratum: Spectroscopy and Ground-State Transfer of Ultracold Bosonic ^{39}K^{133}Cs Molecules [Phys. Rev. Lett. 135, 203401 (2025)].

Physical review letters·2026
Same journal

Erratum: Lifetime of the ^{2}F_{7/2} Level in Yb^{+} for Spontaneous Emission of Electric Octupole Radiation [Phys. Rev. Lett. 127, 213001 (2021)].

Physical review letters·2026
Same journal

Laser-Plasma Based Seeded Free Electron Laser in the High-Gain Regime.

Physical review letters·2026
Same journal

Parent Hamiltonians for Stabilizer Quantum Many-Body Scars.

Physical review letters·2026
Same journal

Properties of Heavy Cosmic Nuclei Phosphorus, Chlorine, Argon, Potassium, and Calcium: Results from the Alpha Magnetic Spectrometer.

Physical review letters·2026
Same journal

Role of Spin-Isospin Symmetries in Nuclear β-Decays.

Physical review letters·2026
See all related articles

Related Experiment Video

Updated: Nov 25, 2025

Synthesis and Operation of Fluorescent-core Microcavities for Refractometric Sensing
08:12

Synthesis and Operation of Fluorescent-core Microcavities for Refractometric Sensing

Published on: March 13, 2013

13.1K

Floquet Cavity Electromagnonics.

Jing Xu1, Changchun Zhong2, Xu Han1

  • 1Center for Nanoscale Materials, Argonne National Laboratory, Lemont, Illinois 60439, USA.

Physical Review Letters
|December 18, 2020
PubMed
Summary
This summary is machine-generated.

Floquet engineering enables coherent control of magnon-microwave photon interactions in hybrid magnonics. This breakthrough introduces Floquet ultrastrong coupling, advancing coherent signal processing applications.

More Related Videos

Fabrication and Testing of Microfluidic Optomechanical Oscillators
09:10

Fabrication and Testing of Microfluidic Optomechanical Oscillators

Published on: May 29, 2014

12.4K
Recombination Dynamics in Thin-film Photovoltaic Materials via Time-resolved Microwave Conductivity
11:30

Recombination Dynamics in Thin-film Photovoltaic Materials via Time-resolved Microwave Conductivity

Published on: March 6, 2017

12.0K

Related Experiment Videos

Last Updated: Nov 25, 2025

Synthesis and Operation of Fluorescent-core Microcavities for Refractometric Sensing
08:12

Synthesis and Operation of Fluorescent-core Microcavities for Refractometric Sensing

Published on: March 13, 2013

13.1K
Fabrication and Testing of Microfluidic Optomechanical Oscillators
09:10

Fabrication and Testing of Microfluidic Optomechanical Oscillators

Published on: May 29, 2014

12.4K
Recombination Dynamics in Thin-film Photovoltaic Materials via Time-resolved Microwave Conductivity
11:30

Recombination Dynamics in Thin-film Photovoltaic Materials via Time-resolved Microwave Conductivity

Published on: March 6, 2017

12.0K

Area of Science:

  • Quantum physics
  • Condensed matter physics
  • Materials science

Background:

  • Hybrid magnonics is a key platform for coherent information processing.
  • Controlling magnon interactions with other carriers, like microwave photons, is crucial but challenging.
  • Existing electromagnonic systems lack on-demand control over these interactions.

Purpose of the Study:

  • To demonstrate coherent control over magnon-microwave photon coupling using Floquet engineering.
  • To introduce and explore the Floquet ultrastrong coupling regime in cavity electromagnonics.
  • To enable new possibilities for magnon-based coherent signal processing.

Main Methods:

  • Implementing Floquet engineering via periodic temporal modulation.
  • Developing a novel Floquet cavity electromagnonic system.
  • Analyzing the manipulation of hybridized cavity electromagnonic modes.

Main Results:

  • Achieved coherent control over magnon-microwave photon coupling.
  • Demonstrated a new Floquet ultrastrong coupling regime.
  • Observed Floquet splitting comparable to or exceeding mode level spacing, surpassing the rotating-wave approximation.

Conclusions:

  • Floquet engineering provides a powerful tool for controlling hybrid magnonic systems.
  • The discovered Floquet ultrastrong coupling regime opens new avenues for quantum technologies.
  • This work significantly advances the potential applications of hybrid magnonics in information processing.