Transcript NASC 1110
Lecture 8
Examples of Magnetic Fields
Chapter 19.7 19.10
Outline
• Long Wire and Ampere’s Law
• Two Parallel Contours
• Solenoid
Magnetic Field of a Wire
Charges flowing in a single wire produce magnetic
field, whose field lines circle the wire in the
direction according to the right hand rule.
The magnetic field strength (B) is the same at all
points of the circular path around the wire.
B at distance r from a wire carrying current I is:
0 I
B =
2r
0 is the permeability of free space
0 4 107 T m / A
Ampere’s Law
Andre-Marie Ampere proposed how to calculate
the magnetic field in an arbitrarily shaped wire.
Ampere’s circuital law states that over any
closed path around the wire (B‖l) = 0 I
This law gives an identical result to that for a
long, straight current.
Ampere’s circuital law is only valid for the
currents and fields constant in time.
Magnetic Field Between Two
Parallel Conductors
Two current-carrying conductors
exert magnetic forces on each other.
Consider 2 long, straight wires of
length l carrying currents I1 and I2
and separated by a distance d.
0 I2
B2 =
2d
0 I2
0 I1 I2
F1=B2 I1 l = I1 l = l
2d
2d
Example
Two wires positioned one above another parallel to
the Earth’s surface have a weight per unit length of
104 N/m each. If they are separated by 1 cm and
not affected by Earth’s magnetic field, what must
be the current (same in both wires) to keep the
upper wire in the air?
F1 = mg
0 I1 I2
F2 = l
2d
mg
0 I2
l
2d
=
I = (2d mg/l0) = (107 dmg/2) = 2.2 A
Two Parallel Conductors
F1 0 I1 I2
=
l
2d
The magnetic force exerted by one
wire onto the other is directed
toward the other wire.
Thus, the wires carrying currents in the same
direction attract each other.
This result is derived using the right-hand rule No
1 and in compliance with Newton’s third law.
Definition of the unit of current, ampere.
magnetic
fieldsin
originate
electric charges.
1All
A is
the current
2 wiresfrom
1 mmoving
apart attracting
each
other with the force per unit length of 2 107 N/m.
Magnetic Field of a Solenoid
Solenoid is a coil of several closely spaced loops.
Consider a solenoid of length l and total number of turns N
carrying a current I.
The magnetic field inside the solenoid will be:
B = 0 n I
n = N/l
Current in a Solenoid
Problem: A superconducting solenoid is designed
to generate a magnetic field of 5 T.
If the solenoid winding has 1000 turns/m, what is
the required current?
B = 0 n I
B
I =
0 n
n = 1000
I = 5/(4107 103) = 3978 A
Ampere’s Law for a Solenoid
The magnetic field B inside a solenoid is uniform
and parallel to its axis.
B outside a solenoid is virtually zero.
(B‖l) = BL = 0 N I
N
B = 0 I = 0 n I
L
Picture of a solenoid field
Summary
• Ampere’s law is a relation between the current in
an arbitrarily shaped wire and the magnetic field
produced by the wire.
• Magnetic field of a closed loop increases the
magnetic field set up by a piece of wire.