Video: المجالات الكهربائية المستحثة: التطبيقات

The induced electric field produced by a changing magnetic field differs from the electrostatic field generated by static charge distribution.

The induced electric field is non-conservative as its net work for moving a charge in a closed path is non-zero, whereas the electrostatic field is conservative.

Consider a circular coil with a 0.25 meter radius. A magnetic field perpendicular to the plane of the coil is directed inward and starts increasing at a constant rate of 3 t Tesla per second. Calculate the induced emf and electric field at 5 seconds.

List the known and unknown quantities.

As the magnetic field is perpendicular to the plane, the magnetic flux is a product of the coil's magnetic field and area.

Using Faraday's law, the induced emf based on the magnetic flux is 2.94 Volts at 5 seconds.

Also, induced emf can be expressed in terms of induced electric field.

As the electric field vector is tangential to the coil, whose circumference is 2-pi-r, the equation can be rearranged to find the induced electric field—1.87 Volts per meter.

An important distinction exists between the electric field induced by a changing magnetic field and the electrostatic field produced by a fixed charge distribution. Specifically, the induced electric field is nonconservative because it does not work in moving a charge over a closed path. In contrast, the electrostatic field is conservative and does no net work over a closed path. Hence, electric potential can be associated with the electrostatic field but not the induced field. The following equations represent the distinction between the two types of electric fields:

Equation1

Equation2

When the magnetic flux through a circuit changes, a nonconservative electric field is induced, which drives current through the circuit. However, when there is no conducting path in free space, it can be treated as if a conducting path were present; that is, nonconservative electric fields are induced wherever the magnetic flux through a circuit changes, whether or not a conducting path is present.

Tags

Induced Electric Fields Changing Magnetic Field Electrostatic Field Conservative Field Nonconservative Electric Field Magnetic Flux Circuit Current Electric Potential Charge Distribution Closed Path

From Chapter 30:

article

Now Playing

30.7 : Induced Electric Fields: Applications

Electromagnetic Induction

1.4K Views

article

30.1 : التعريفي

Electromagnetic Induction

3.7K Views

article

30.2 : قانون فاراداي

Electromagnetic Induction

3.6K Views

article

30.3 : قانون لينز

Electromagnetic Induction

3.3K Views

article

30.4 : الحركة EMF

Electromagnetic Induction

3.0K Views

article

30.5 : فاراداي ديسك دينامو

Electromagnetic Induction

1.9K Views

article

30.6 : المجالات الكهربائية المستحثة

Electromagnetic Induction

3.4K Views

article

30.8 : التيارات الدوامة

Electromagnetic Induction

1.4K Views

article

30.9 : تيار الإزاحة

Electromagnetic Induction

2.7K Views

article

30.10 : أهمية تيار الإزاحة

Electromagnetic Induction

4.2K Views

article

30.11 : المجالات الكهرومغناطيسية

Electromagnetic Induction

2.0K Views

article

30.12 : معادلة ماكسويل للكهرومغناطيسية

Electromagnetic Induction

2.9K Views

article

30.13 : التماثل في معادلات ماكسويل

Electromagnetic Induction

3.1K Views

article

30.14 : قانون أمبير ماكسويل: حل المشكلات

Electromagnetic Induction

433 Views

article

30.15 : الشكل التفاضلي لمعادلات ماكسويل

Electromagnetic Induction

338 Views

See More

Copyright © 2025 MyJoVE Corporation. All rights reserved