Explain how Ampère’s law relates the magnetic field produced by a current to the value of the current
Calculate the magnetic field from a long straight wire, either thin or thick, by Ampère’s law
A fundamental property of a static magnetic field is that, unlike an electrostatic field, it is not conservative. A conservative field is one that does the same amount of work on a particle moving between two different points regardless of the path chosen. Magnetic fields do not have such a property. Instead, there is a relationship between the magnetic field and its source, electric current. It is expressed in terms of the line integral of
and is known as
Ampère’s law . This law can also be derived directly from the Biot-Savart law. We now consider that derivation for the special case of an infinite, straight wire.
[link] shows an arbitrary plane perpendicular to an infinite, straight wire whose current
I is directed out of the page. The magnetic field lines are circles directed counterclockwise and centered on the wire. To begin, let’s consider
over the closed paths
M and
N . Notice that one path (
M ) encloses the wire, whereas the other (
N ) does not. Since the field lines are circular,
is the product of
B and the projection of
dl onto the circle passing through
If the radius of this particular circle is
r , the projection is
and
For path
M , which circulates around the wire,
and
Path
N , on the other hand, circulates through both positive (counterclockwise) and negative (clockwise)
(see
[link] ), and since it is closed,
Thus for path
N ,
The extension of this result to the general case is Ampère’s law.
Ampère’s law
Over an arbitrary closed path,
where
I is the total current passing through any open surface
S whose perimeter is the path of integration. Only currents inside the path of integration need be considered.
To determine whether a specific current
I is positive or negative, curl the fingers of your right hand in the direction of the path of integration, as shown in
[link] . If
I passes through
S in the same direction as your extended thumb,
I is positive; if
I passes through
S in the direction opposite to your extended thumb, it is negative.
Problem-solving strategy: ampère’s law
To calculate the magnetic field created from current in wire(s), use the following steps:
Identify the symmetry of the current in the wire(s). If there is no symmetry, use the Biot-Savart law to determine the magnetic field.
Determine the direction of the magnetic field created by the wire(s) by right-hand rule 2.
Chose a path loop where the magnetic field is either constant or zero.
Calculate the current inside the loop.
Calculate the line integral
around the closed loop.
Equate
with
and solve for
Using ampère’s law to calculate the magnetic field due to a wire
Use Ampère’s law to calculate the magnetic field due to a steady current
I in an infinitely long, thin, straight wire as shown in
[link] .
Strategy
Consider an arbitrary plane perpendicular to the wire, with the current directed out of the page. The possible magnetic field components in this plane,
and
are shown at arbitrary points on a circle of radius
r centered on the wire. Since the field is cylindrically symmetric, neither
nor
varies with the position on this circle. Also from symmetry, the radial lines, if they exist, must be directed either all inward or all outward from the wire. This means, however, that there must be a net magnetic flux across an arbitrary cylinder concentric with the wire. The radial component of the magnetic field must be zero because
Therefore, we can apply Ampère’s law to the circular path as shown.
Solution
Over this path
is constant and parallel to
so
Thus Ampère’s law reduces to
Finally, since
is the only component of
we can drop the subscript and write
This agrees with the Biot-Savart calculation above.
Significance
Ampère’s law works well if you have a path to integrate over which
has results that are easy to simplify. For the infinite wire, this works easily with a path that is circular around the wire so that the magnetic field factors out of the integration. If the path dependence looks complicated, you can always go back to the Biot-Savart law and use that to find the magnetic field.
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