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o Aim of the lecture Calculation of Magnetic Fields
Biot-Savart Law Magnetic field, B
Ampres Law B field Case of static E field
o Main learning outcomes familiarity with
Calculation of Magnetic Fields from currents Biot-Savart Law Amperes Law
Lecture 8
o We understand:o the source of electric field is the electric charges,
o But there are no magnetic monopoles, o which means no magnetic chargeso So where do magnetic fields come from?
The answer is that it must be remembered
There is a VERY close connection between electric and magnetic fields
A magnetic field is just an electric field in motionor An electric field is just a magnetic field in motion
( loosely speaking – there is just one field, it is an electromagnetic field It becomes pure magnetic or electric when the charge is stationary)
o Hence it is possible to have a magnetic field when there are no magnetic charges.
o What is needed is electric charges in motion This is a CURRENT
However:
o The shape of the field that can be made is not the same A stationary electric charge makes a monopole electric field Two opposite electric charges makes an electric dipole field A string of electric charges moving in a loop (a current loop) makes a dipole magnetic field There is no monopole magnetic field observed in nature simply because there are no magnetic monopoles seen
Monopole electric field (electric charge) (remember this cannot be exactly correct in a 2-D drawing)
Dip0le electric field (electric charges)Dipole magnetic field (electric charges)
Same general field patternusing a single current loop DIPOLE
More detail on how to compute Magnetic Fields caused by currents
s
ds
o The Biot-Savart Law tells for each current element, Ids the size and direction of the B field produced
o The total field is then the sum of all such elements.
ds
This current element
Produces a B field elementof constant magnitude onthis ring
Also a constantmagnitude on thisring
The element contributes everywhere in space according to the Biot-Savart Formula
ds
To get the total field here
Need to add all the contributions from all the currentelements
Vector Integral needed
∫B = ∫Note: in principleo All currents in universeo But because of 1/r2
o Only nearby matter
Biot Savart
What this says is simply that integrating the B field round any closed loopwill give you an answer which is proportional to the current flowingthrough the loop. It doesn't matter what shape the loop is
(this is the case where the electric field is constant – see next slide)
Ampère
The complete version is this:
This equation relates the magnetic field to the motionof charges and the change inelectric field.
In many cases the electric fieldis constant, so that the secondterm can be dropped.
This is the case for fixed currentdistributions, such as currents inwires.
( which we did on the previous transparency )
J is current density
So this is Ampere's Lawin differential form
It is telling us how themagnetic and electricfields are related to theelectric charges.
(You are not expected to manipulate Maxwell’s equations in this course)
Next Lecture: Faraday’s Law of Induction