Magnetic Field and Work [PDF]

Magnetic Field and Work ÎMagnetic

force is always perpendicular to velocity

‹ Therefore

B field does rno work! r r r ‹ Why? Because ∆K = F ⋅ ∆x = F ⋅ ( v ∆t ) = 0 ÎConsequences ‹ Kinetic

energy does not change ‹ Speed does not change ‹ Only direction changes r ‹ Particle moves in a circle (if v ⊥

r B)

PHY2049: Chapter 28

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Trajectory in a Constant Magnetic Field ÎA

charge q enters B field with velocity v perpendicular to B. What path will q follow? is always ⊥ velocity and ⊥ B ‹ Path will be a circle. F is the centripetal force needed to keep the charge in its circular orbit. Let’s calculate radius R ‹ Force

x x x x x x x x x x x x x x B x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x vx x F F v

v F

q

R PHY2049: Chapter 28

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Circular Motion of Positive Particle x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x

v

B F

q

x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x

2

mv = qvB R

mv R= qB PHY2049: Chapter 28

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Magnetic Force ÎTwo

particles of the same charge enter a magnetic field with the same speed. Which one has the bigger mass? ‹A ‹B ‹ Both

masses are equal ‹ Cannot tell without more info

x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x

mv R= qB

x x x x x x x x x x x x

Bigger mass means larger inertia, less acceleration, thus bigger radius PHY2049: Chapter 28

A

B

4

Work and Energy ÎA

charged particle enters a uniform magnetic field. What happens to the kinetic energy of the particle? ‹ (1) ‹ (2) ‹ (3) ‹ (4) ‹ (5)

it it it it it

increases decreases stays the same depends on the direction of the velocity depends on the direction of the magnetic field

Magnetic field does no work, so K is constant

PHY2049: Chapter 28

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Cosmic Ray Example with energy 1 MeV move ⊥ earth B field of 0.5 gauss or 5 × 10-5 T. Find radius & frequency of orbit.

ÎProtons

K=

1 mv 2 2

2K ⇒ v= m

( )(

)

K = 106 1.6 × 10−19 =1.6 × 10−13 J m = 1.67 × 10−27 kg

mv 2mK R= = eB eB

R = 2900 m

1 v v eB f = = = = T 2π R 2π ( mv / eB ) 2π m

f = 760 Hz

Frequency is independent of v! PHY2049: Chapter 28

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Helical Motion in B Field ÎVelocity

of particle has 2 components r r r ‹ v = v + v⊥ (parallel to B and perp. to B) ‹ Only

v⊥ = v sinφ contributes to circular motion ‹ v|| = v cosφ is unchanged ÎSo

the particle moves in a helical path

‹ v||

is the constant velocity along the B field ‹ v⊥ is the velocity around the circle

v|| v

v⊥

B

φ

mv⊥ R= qB

PHY2049: Chapter 28

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Helical Motion in Earth’s B Field

Particles moving along field lines cause Aurora Borealis and Australis: http://science.nasa.gov/spaceweather/aurora/gallery_01oct03.html PHY2049: Chapter 28

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Mass Spectrometer ÎOriginally

developed by physicists, now an important tool in chemistry, biology, environmental studies, forensics, pharmaceutics, etc.

ÎSample

is vaporized, broken into fragments of molecules, which are positively ionized. Positive ions are first accelerated by a potential difference V, and then their trajectories are bent by B. Varying B (sometimes V) allows ions of different masses to reach the detector.

PHY2049: Chapter 28

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Mass Spectrometer (simplified) ÎSample

is vaporized, broken into fragments of molecules, which are positively ionized. Positive ions are first accelerated by a potential difference V, and then their trajectories are bent by B. Varying B (sometimes V) allows ions of different masses to reach the detector. ‹ Spectrometer

determines mass from B (sometimes from V)

q ( Br ) 2 m= 2V

2r

D

PHY2049: Chapter 28

detector

10

Torque on Current Loop a

Î Rectangular

current loop in uniform magnetic field (lengths a & b) Forces in left & right branches are 0 ‹ Force in top branch is into plane ‹ Force in bottom branch is out of plane ‹

Î Equal

b

forces give net torque!

Bottom side up, top side down (RHR) ‹ Rotates around horizontal axis ‹

τ = Fd = ( iBa ) b = iBab = iBA

ε

= NiA ⇒ “magnetic dipole moment”

B

b

a Plane normal is ⊥ B (θ = 90°)

Assuming N turns ‹ τ = µB, true for any shape!! ‹

Î If

plane tilted angle θ to B field τ = µBsinθ ‹ θ is angle between normal and B ‹

PHY2049: Chapter 28

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Magnetic Dipole Moment

PHY2049: Chapter 28

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Torque Example ÎA

3-turn circular loop of radius 3 cm carries 5A current in a B field of 2.5 T. Loop is tilted 30° to B field. 30°

2 2 Î µ = 3iπ r = 3 × 5 × 3.14 × ( 0.03 ) = 0.0339 A ⋅ m 2

Îτ

= µ B sin 30 = 0.0339 × 2.5 × 0.5 = 0.042 N ⋅ m

ÎRotation

is always in direction to align µ with B field PHY2049: Chapter 28

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Magnetic Force ÎA

rectangular current loop is in a uniform magnetic field. What direction is the net force on the loop? ‹ (a)

+x ‹ (b) + y ‹ (c) zero ‹ (d) – x ‹ (e) – y

Forces cancel on opposite sides of loop

B

z

y x PHY2049: Chapter 28

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Electromagnetic Flowmeter

E

¾ ¾ ¾ ¾ ¾

Moving ions in the blood are deflected by magnetic force Positive ions deflected down, negative ions deflected up This separation of charge creates an electric field E pointing up E field creates potential difference V = Ed between the electrodes The velocity of blood flow is measured by v = E/B PHY2049: Chapter 28

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Hall Effect: Do + or – Charges Carry Current?

Î

+ charges moving counter-clockwise experience upward force

Î

– charges moving clockwise experience upward force

Î

Upper plate at higher potential

Î

Upper plate at lower potential

Very quickly, equilibrium between electrostatic & magnetic forces is established and potential difference stops growing: V VH = vdrift Bw = "Hall Voltage" Fdown = qEinduced = q H Fup = qvdrift B w ¾ This type of experiment led to the discovery (E. Hall, 1879) that current in conductors is carried by negative charges ¾ Hall effect is used to measure moderate to moderately high B (10-4 T – 3 T) ¾ It is also used to measure the speed of computer hard drive PHY2049: Chapter 28

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FAQ on Magnetic Field and Work Î Magnetic

force does no work. But an electric motor (=a current loop in B) does work. Where does this work come from? Magnetic force does no work on a moving charge ‹ Magnetic torque on a current loop does work: ∆W=τ∆θ ‹

Î There

is no net force, only torque, on a current loop (=magnetic dipole moment) in B. But two bar magnets (=collection of atomic magnetic dipole moments) attract each other. How come? There is no net force, only torque, on magnetic dipole moment in uniform B ‹ When B is non-uniform, then there is net force. Can be shown that the direction of this force is such that magnetic dipole moment is attracted to the region of high B. ‹

Î Magnetic

force does no work. But when two bar magnets are attracted to each other, there must be work done by B. Something is not right here. Magnetic force does no work on a moving charge ‹ When a magnetic dipole moment moves as a result of force due to nonuniform B, then this force does work. There is no contradiction. ‹

PHY2049: Chapter 28

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