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Standing Waves in a Cavity01:28

Standing Waves in a Cavity

1.6K
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:
1.6K
Sound Waves: Interference00:53

Sound Waves: Interference

5.0K
Sound waves can be modeled either as longitudinal waves, wherein the molecules of the medium oscillate around an equilibrium position, or as pressure waves. When two identical waves from the same source superimpose on each other, the combination of two crests or two troughs results in amplitude reinforcement known as constructive interference. If two identical waves, that are initially in phase, become out of phase because of different path lengths, the combination of crests with troughs...
5.0K
Sound as Pressure Waves01:17

Sound as Pressure Waves

4.7K
Sound waves, which are longitudinal waves, can be modeled as the displacement amplitude varying as a function of the spatial and temporal coordinates. As a column of the medium is displaced, its successive columns are also displaced. As the successive displacements differ relatively, a pressure difference with the surrounding pressure is created. The gauge pressure varies across the medium.
The pressure fluctuation depends on the difference in displacements between the successive points in the...
4.7K
Sound Waves: Resonance01:14

Sound Waves: Resonance

3.6K
Resonance is produced depending on the boundary conditions imposed on a wave. Resonance can be produced in a string under tension with symmetrical boundary conditions (i.e., has a node at each end). A node is defined as a fixed point where the string does not move. The symmetrical boundary conditions result in some frequencies resonating and producing standing waves, while other frequencies interfere destructively. Sound waves can resonate in a hollow tube, and the frequencies of the sound...
3.6K
Perception of Sound Waves01:01

Perception of Sound Waves

5.9K
The human ear is not equally sensitive to all frequencies in the audible range. It may perceive sound waves with the same pressure but different frequencies as having different loudness. Moreover, the perception of sound waves depends on the health of an individual's ears, which decays with age. The health of one's ears may also be affected by regular exposure to loud noises.
The pitch of a sound depends on the frequency and the pressure amplitude of the source. Two sounds of the same...
5.9K
Double Resonance Techniques: Overview01:12

Double Resonance Techniques: Overview

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Double resonance techniques in Nuclear Magnetic Resonance (NMR) spectroscopy involve the simultaneous application of two different frequencies or radiofrequency pulses to manipulate and observe two distinct nuclear spins. One important application of double resonance is spin decoupling, which selectively suppresses coupling with one type of nucleus while observing the NMR signal from another nucleus, simplifying the spectrum and enhancing resolution.
Spin decoupling is usually achieved by...
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Video Experimental Relacionado

Updated: Mar 14, 2026

Recording Ultra-Realistic Full-Color Analog Holograms for Use in a Moving Hologram Display
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Recording Ultra-Realistic Full-Color Analog Holograms for Use in a Moving Hologram Display

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Hologramas para la acústica

Kai Melde1, Andrew G Mark1, Tian Qiu1

  • 1Max Planck Institute for Intelligent Systems, Heisenbergstrasse 3, 70569 Stuttgart, Germany.

Nature
|September 23, 2016
PubMed
Resumen
Este resumen es generado por máquina.

Los investigadores desarrollaron hologramas acústicos monolíticos para el control preciso del haz de ultrasonido. Este avance permite campos acústicos 3D complejos, superando las tecnologías actuales para aplicaciones en manipulación, imágenes y transferencia de energía.

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Área de la Ciencia:

  • Holografía acústica
  • Reconstrucción del frente de onda
  • Generación de campo acústico 3D

Sus antecedentes:

  • Las técnicas holográficas son cruciales para el control espacial de los campos ópticos y acústicos.
  • La holografía generada por computadora calcula los perfiles de fase para la reconstrucción del frente de onda.
  • Las aplicaciones actuales de ultrasonido que utilizan fuentes discretas tienen grados de libertad limitados.

Objetivo del estudio:

  • Introducir hologramas acústicos monolíticos para la generación arbitraria de haces de ultrasonido.
  • Para lograr mayores grados de libertad en la reconstrucción del frente de onda acústica.
  • Para demostrar nuevas aplicaciones en la manipulación ultrasónica y la transferencia de energía sin contacto.

Principales métodos:

  • Fabricación rápida de hologramas acústicos monolíticos.
  • Reconstrucción de campos de presión acústica limitados por la difracción.
  • Utilizando distribuciones complejas de presión y fase 3D para la manipulación.

Principales resultados:

  • Logró grados de libertad de reconstrucción dos órdenes de magnitud más altos que las matrices por fases comerciales.
  • Se ha demostrado la manipulación controlada por ultrasonidos de sólidos y líquidos en diversos medios.
  • Desarrolló una técnica barata y escalable para la holografía acústica.

Conclusiones:

  • Los hologramas acústicos monolíticos ofrecen avances significativos con respecto a los métodos tradicionales.
  • La tecnología permite nuevas capacidades en dirección de haz, transferencia de energía sin contacto e imágenes médicas.
  • Los hologramas acústicos están listos para impulsar la innovación en diversas aplicaciones de ultrasonido.