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Related Concept Videos

Standing Waves in a Cavity01:28

Standing Waves in a Cavity

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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Related Experiment Video

Updated: Jun 14, 2026

Preparation of Silica Nanoparticles Through Microwave-assisted Acid-catalysis
09:43

Preparation of Silica Nanoparticles Through Microwave-assisted Acid-catalysis

Published on: December 16, 2013

Microwave effects in silicon low dimensional nanostructures.

Enrico Prati1, Rossella Latempa, Marco Fanciulli

  • 1Laboratorio Nazionale Materiali e Dispositivi per la Microelettronica, Consiglio Nazionale delle Ricerche--Istituto Nazionale per la Fisica della Materia, Via Olivetti 2, 1-20041 Agrate Brianza, Italy.

Journal of Nanoscience and Nanotechnology
|April 2, 2010
PubMed
Summary
This summary is machine-generated.

Microwave irradiation affects electron systems in silicon nanostructures, influencing electron transitions. This impacts single electron trapping and spin manipulation in nanoelectronic devices.

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Area of Science:

  • Solid State Physics
  • Quantum Electronics
  • Nanotechnology

Background:

  • Low-dimensional electron systems in silicon nanostructures are crucial for advanced electronics.
  • Understanding electron behavior under external stimuli like microwave irradiation is key to device performance.
  • Confinement effects in zero-dimensional systems present unique quantum phenomena.

Purpose of the Study:

  • To review the impact of microwave irradiation on electron systems in silicon nanostructures.
  • To analyze electron transition probabilities under varying temperatures and energy scales.
  • To explore phenomena like photon-assisted tunneling and its consequences.

Main Methods:

  • Review of theoretical models and experimental findings on microwave effects.
  • Analysis of electron trapping in point defects and donor atoms.
  • Description of microwave-dependent capture, emission, and tunneling processes.

Main Results:

  • Microwave irradiation significantly alters elastic and inelastic electron transition probabilities.
  • Photon-assisted tunneling and microwave-dependent capture/emission are observed in confined systems.
  • The study details effects on single spin resonance detection and spin manipulation.

Conclusions:

  • Microwave irradiation offers a tunable mechanism to control electron behavior in silicon nanostructures.
  • Understanding these effects is vital for developing novel quantum devices and spintronic applications.
  • The findings provide insights into electron dynamics at the nanoscale.