Chapter 19 Magnetism.

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Presentation transcript:

Chapter 19 Magnetism

Hans Christian Oersted 1777 – 1851 Best known for observing that a compass needle deflects when placed near a wire carrying a current First evidence of a connection between electric and magnetic phenomena

Clicker An electron which moves with a speed of 3.0  104 m/s parallel to a uniform magnetic field of 0.40 T experiences a force of what magnitude? (e = 1.6  1019 C)   a. 4.8  1014 N b. 1.9  1015 N c. 2.2  1024 N d. zero

Magnetic Fields – Long Straight Wire A current-carrying wire produces a magnetic field The compass needle deflects in directions tangent to the circle The compass needle points in the direction of the magnetic field produced by the current

Direction of the Field of a Long Straight Wire Right Hand Rule #2 Grasp the wire in your right hand Point your thumb in the direction of the current Your fingers will curl in the direction of the field

Magnitude of the Field of a Long Straight Wire The magnitude of the field at a distance r from a wire carrying a current of I is µo = 4  x 10-7 T.m / A µo is called the permeability of free space

André-Marie Ampère 1775 – 1836 Credited with the discovery of electromagnetism Relationship between electric currents and magnetic fields

Ampère’s Law Ampère found a procedure for deriving the relationship between the current in an arbitrarily shaped wire and the magnetic field produced by the wire Ampère’s Circuital Law B|| Δℓ = µo I Sum over the closed path

Ampère’s Law, cont Choose an arbitrary closed path around the current Sum all the products of B|| Δℓ around the closed path

Ampère’s Law to Find B for a Long Straight Wire Use a closed circular path The circumference of the circle is 2  r This is identical to the result previously obtained

Magnetic Force Between Two Parallel Conductors The force on wire 1 is due to the current in wire 1 and the magnetic field produced by wire 2 The force per unit length is:

Force Between Two Conductors, cont Parallel conductors carrying currents in the same direction attract each other Parallel conductors carrying currents in the opposite directions repel each other

Defining Ampere and Coulomb The force between parallel conductors can be used to define the Ampere (A) If two long, parallel wires 1 m apart carry the same current, and the magnitude of the magnetic force per unit length is 2 x 10-7 N/m, then the current is defined to be 1 A The SI unit of charge, the Coulomb (C), can be defined in terms of the Ampere If a conductor carries a steady current of 1 A, then the quantity of charge that flows through any cross section in 1 second is 1 C

Magnetic Field of a Current Loop The strength of a magnetic field produced by a wire can be enhanced by forming the wire into a loop All the segments, Δx, contribute to the field, increasing its strength

Magnetic Field of a Current Loop – Total Field

Magnetic Field of a Current Loop – Equation The magnitude of the magnetic field at the center of a circular loop with a radius R and carrying current I is With N loops in the coil, this becomes

Magnetic Field of a Solenoid If a long straight wire is bent into a coil of several closely spaced loops, the resulting device is called a solenoid It is also known as an electromagnet since it acts like a magnet only when it carries a current

Magnetic Field of a Solenoid, 2 The field lines inside the solenoid are nearly parallel, uniformly spaced, and close together This indicates that the field inside the solenoid is nearly uniform and strong The exterior field is nonuniform, much weaker, and in the opposite direction to the field inside the solenoid

Magnetic Field in a Solenoid, 3 The field lines of a closely spaced solenoid resemble those of a bar magnet

Magnetic Field in a Solenoid, Magnitude The magnitude of the field inside a solenoid is constant at all points far from its ends B = µo n I n is the number of turns per unit length n = N / ℓ The same result can be obtained by applying Ampère’s Law to the solenoid

Magnetic Field in a Solenoid from Ampère’s Law A cross-sectional view of a tightly wound solenoid If the solenoid is long compared to its radius, we assume the field inside is uniform and outside is zero Apply Ampère’s Law to the blue dashed rectangle Gives same result as previously found

Magnetic Effects of Electrons – Orbits An individual atom should act like a magnet because of the motion of the electrons about the nucleus Each electron circles the atom once in about every 10-16 seconds This would produce a current of 1.6 mA and a magnetic field of about 20 T at the center of the circular path However, the magnetic field produced by one electron in an atom is often canceled by an oppositely revolving electron in the same atom

Magnetic Effects of Electrons – Orbits, cont The net result is that the magnetic effect produced by electrons orbiting the nucleus is either zero or very small for most materials

Magnetic Effects of Electrons – Spins Electrons also have spin The classical model is to consider the electrons to spin like tops It is actually a quantum effect

Magnetic Effects of Electrons – Spins, cont The field due to the spinning is generally stronger than the field due to the orbital motion Electrons usually pair up with their spins opposite each other, so their fields cancel each other That is why most materials are not naturally magnetic

Summary Torque on a current loop, electrical motor Magnetic field around a current carrying wire. Ampere’s law Solenoid Material magnetism