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Magnetic Fields01:27

Magnetic Fields

7.4K
A moving charge or a current creates a magnetic field in the surrounding space, in addition to its electric field. The magnetic field exerts a force on any other moving charge or current that is present in the field. Like an electric field, the magnetic field is also a vector field. At any position, the direction of the magnetic field is defined as the direction in which the north pole of a compass needle points.
A magnetic field is defined by the force that a charged particle experiences...
7.4K
Magnetic Field of a Solenoid01:18

Magnetic Field of a Solenoid

5.9K
A solenoid is a conducting wire coated with an insulating material, wound tightly in the form of a helical coil. The magnetic field due to a solenoid is the vector sum of the magnetic fields due to its individual turns. Therefore, for an ideal solenoid, the magnetic field within the solenoid is directly proportional to the number of turns per unit length and the current. Conversely, the magnetic field outside the solenoid is zero.
Consider a solenoid with 100 turns wrapped around a cylinder of...
5.9K
Magnetic Field Lines01:19

Magnetic Field Lines

5.8K
The representation of magnetic fields by magnetic field lines is very useful in visualizing the strength and direction of the magnetic field. Each of the magnetic field lines forms a closed loop. The field lines emerge from the north pole (N), loop around to the south pole (S), and continue through the bar magnet back to the north pole.
Magnetic field lines follow several hard-and-fast rules:
5.8K
Energy In A Magnetic Field01:24

Energy In A Magnetic Field

2.8K
If a magnetic field is sustained, there must be a current in a closed circuit or loop, implying some energy has been spent in creating the field. If this energy is not dissipated via the circuit's resistance, it is stored in the field.
Take an ideal inductor with zero resistance. Although it's practically impossible, assume that the coil's resistance is so small that it is practically negligible. The loss of the field's energy to dissipate thermal energy (or heat) is thus...
2.8K
Magnetic Field Of A Current Loop01:16

Magnetic Field Of A Current Loop

6.4K
Consider a circular loop with a radius a, that carries a current I. The magnetic field due to the current at an arbitrary point P along the axis of the loop can be calculated using the Biot-Savart law.
6.4K
Magnetic Field due to Moving Charges01:23

Magnetic Field due to Moving Charges

11.7K
A stationary charge creates and interacts with the electric field, while a moving charge creates a magnetic field.
Consider a point charge moving with a constant velocity. Like the electric field, the magnetic field at any point is directly proportional to the magnitude of the charge and inversely proportional to the square of the distance between the source point and the field point. However, unlike the electric field, the magnetic field is always perpendicular to the plane containing the line...
11.7K

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Related Experiment Video

Updated: Feb 5, 2026

Focused Ion Beam Lithography to Etch Nano-architectures into Microelectrodes
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Focused Ion Beam Lithography to Etch Nano-architectures into Microelectrodes

Published on: January 19, 2020

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Optically controlled magnetic-field etching on the nano-scale.

Takashi Yatsui1, Toshiki Tsuboi1, Maiku Yamaguchi1

  • 1School of Engineering, University of Tokyo, Bunkyo-ku, Tokyo, 113-8656 Japan.

Light, Science & Applications
|September 1, 2018
PubMed
Summary

Researchers found that magnetic fields, not electric fields, dictate etching properties in nano-scale structures. This discovery offers new insights for advanced nano-fabrication techniques.

Keywords:
nano-scalenear-field etchingoptically controlled magnetic-field interaction

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Electrochemical Etching and Characterization of Sharp Field Emission Points for Electron Impact Ionization
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Area of Science:

  • Materials Science and Nanotechnology
  • Physics and Chemistry

Background:

  • Electric and magnetic fields are crucial in chemical and physical reactions.
  • Magnetic field coupling with electrons is generally weak in the visible spectrum, making it negligible in photo-induced reactions.
  • Understanding field interactions is key for controlling nanoscale processes.

Purpose of the Study:

  • To investigate the role of electric and magnetic fields in the photo-etching of zirconium dioxide (ZrO2) nano-stripe structures.
  • To analyze the polarization dependence of etching properties on nano-scale structure width.
  • To explore novel methods for advanced nano-scale structure fabrication.

Main Methods:

  • Performed photo-etching experiments on ZrO2 nano-stripe structures.
  • Investigated etching rate and profile variations with respect to structure width and light polarization.
  • Utilized finite-difference time-domain (FDTD) numerical calculations to model field distributions.

Main Results:

  • Observed a distinct polarization dependence in the etching properties of ZrO2 nano-stripes.
  • Found that etching characteristics, including rate and profile, are significantly influenced by the structure's width.
  • Numerical simulations revealed that magnetic field distributions, not electric fields, primarily govern the observed polarization-dependent etching.

Conclusions:

  • The study demonstrates that localized magnetic fields play a dominant role in the photo-etching of nano-scale structures.
  • This finding challenges the conventional understanding of field negligible magnetic field interactions in photo-induced reactions.
  • The discovery opens new avenues for precise nano-scale structure fabrication by leveraging magnetic field effects.