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Copyright © 2009 Pearson Education, Inc.
© 2009 Pearson Education, Inc.
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Lecture PowerPoints
Physics for Scientists and Engineers, with Modern
Physics, 4th edition
Giancoli
Chapter 21
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Chapter 21Electric Charge and
Electric Field
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• Static Electricity; Electric Charge and Its Conservation
• Electric Charge in the Atom
• Insulators and Conductors
• Induced Charge; the Electroscope
• Coulomb’s Law
• The Electric Field
• Electric Field Calculations for Continuous Charge Distributions
Units of Chapter 21
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• Field Lines
• Electric Fields and Conductors
• Motion of a Charged Particle in an Electric Field
Units of Chapter 21
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Objects can be charged by rubbing
21-1 Static Electricity; Electric Charge and Its Conservation
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Charge comes in two types,
positive and negative;
like charges repel and opposite charges attract.
21-1 Static Electricity; Electric
Charge and Its Conservation
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Electric charge is conserved – the arithmetic sum of the total charge cannot change in any interaction.
Ie. No net electric charge can be created or destroyed.
21-1 Static Electricity; Electric Charge and Its Conservation
Conservation of Electric Charge
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Atom:
Nucleus (small, massive, positive charge)
Electron cloud (large, very low density, negative charge)
21-2 Electric Charge in the Atom
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Polar molecule: neutral overall, but charge not evenly distributed
21-2 Electric Charge in the Atom
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Conductor:
Charge flows freely
Metals
Insulator:
Almost no charge flows
Most other materials
Some materials are semiconductors.
21-3 Insulators and Conductors
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Metal objects can be charged by conduction:
21-4 Induced Charge; the Electroscope
Note that only electrons (e-) are free to move.
Positive charges (protons) are tightly bound in atomic nucleus.
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They can also be charged by induction, either while connected to ground or not:
21-4 Induced Charge; the Electroscope
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Nonconductors won’t become charged by conduction or induction, but will experience charge separation:
21-4 Induced Charge; the Electroscope
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The electroscope can be used for detecting charge.
21-4 Induced Charge; the Electroscope
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The electroscope can be charged either by conduction or by induction.
21-4 Induced Charge; the Electroscope
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The charged electroscope can then be used to determine the sign of an unknown charge.
21-4 Induced Charge; the Electroscope
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Consider electroscope shown below.Both positive (BLACK) and negative (WHITE) objects cause divergence of leaves.
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Charging by induction
Charge on electroscope is opposite to charge on object brought near electroscope.
Leaves collapse –charge opposite to charge on electroscope
Leaves diverge further – charge the same as charge on electroscope
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Experiment shows that the electric force between two charges is proportional to the product of the charges and inversely proportional to the distance between them.
21-5 Coulomb’s Law
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Coulomb’s law:
This equation gives the magnitude of the force between two charges.
21-5 Coulomb’s Law
221
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The force is along the line connecting the charges, and is attractive if the charges are opposite, and repulsive if they are the same.
21-5 Coulomb’s Law
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Unit of charge: coulomb, C.
The proportionality constant in Coulomb’s law is then:
k = 8.99 x 109 N·m2/C2
Charges produced by rubbing are typically around a microcoulomb:
1 μC = 10-6 C.
21-5 Coulomb’s Law
9.0 x 109 N.m2/C2
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Charge on the electron:
e = 1.602 x 10-19 C.
Electric charge is quantized in units of the electron charge.
21-5 Coulomb’s Law
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The proportionality constant k can also be written in terms of ε0, the permittivity of free space:
21-5 Coulomb’s Law
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21-5 Coulomb’s Law
Conceptual Example 21-1: Which charge exerts the greater force?
Two positive point charges, Q1 = 50 μC and Q2 = 1 μC, are separated by a distance . Which is larger in magnitude, the force that Q1 exerts on Q2 or the force that Q2 exerts on Q1?
Coulomb’s Law and Newton’s third Law both tell us that the forces are equal in magnitude.
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21-5 Coulomb’s LawExample 21-2: Three charges in a line.
Three charged particles are arranged in a line, as shown. Calculate the net electrostatic force on particle 3 (the -4.0 μC on the right) due to the other two charges.
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Example 21-2: Three charges in a line.
Three charged particles are arranged in a line, as shown. Calculate the net electrostatic force on particle 3 (the -4.0 μC on the right) due to the other two charges.
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21-5 Coulomb’s LawExample 21-3: Electric force using vector components.
Calculate the net electrostatic force on charge Q3
shown in the figure due to the charges Q1 and Q2.
attractive is
repulsive is
31
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Example 21-3: Electric force using vector components.
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21-5 Coulomb’s Law
Conceptual Example 21-4: Make the force on Q3
zero.
In the figure, where could you place a fourth charge, Q4 = -50 μC, so that the net force on Q3
would be zero?
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21-5 Coulomb’s Law
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Some Additional Q & A Examples
1. Why is it so?
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1. (a) Negative charges (electrons ) move from fur to plastic giving plastic a negative charge and leaving fur with electron deficit positive charge.
(b) The paper is neutral. When ruler is brought near paper electrons are repelled from the ruler and move to the bottom surface of the paper. This leaves a net positive charge on the top surface of the paper which is closer to the ruler than the negative charge on the bottom surface hence there is an attractive force between the ruler and the paper.
1. A plastic ruler is rubbed on fur. Explain:
(a) How the ruler becomes charged in terms of movement of charges.
(b) Why the ruler can pick up small pieces of paper.
(c) Why the bits of paper often “jump” off soon after being picked up.
(c) Once the paper is in contact with the paper, electrons can transfer from the ruler to the paper giving the paper a net negative charge. This causes a repulsive force and the paper “jumps” off.
1. A plastic ruler is rubbed on fur. Explain:
(a) How the ruler becomes charged in terms of movement of charges.
(b) Why the ruler can pick up small pieces of paper.
(c) Why the bits of paper often “jump” off soon after being picked up.
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2. If you walk briskly across a carpet, you often experience a spark upon touching a door knob. (a) What causes this? (b) How might it be prevented?
The soles of your shoes are usually a good insulator and can become charged by friction when walking across the carpet which in turn induces a charge on your body. Your body can be charged to several thousand volts in this way. On touching the (uncharged conducting) door knob a spark can jump from your hand to the door knob. This could be prevented by spraying the carpet with an anti-static spray.
3. Why do electrostatic experiments not work well on humid days?
Moist (humid) air is a better conductor than dry air and allows charge to leak away by conduction thought the air.
4. A positive charge is brought very near an uncharged isolated conductor. The conductor is then grounded while the charge is kept near. Is the conductor charged positively, negatively, or not at all if
(a) the charge is taken away and then the ground connection is removed and(b) the ground connection is removed and then the charge is taken away?
(a) If the charge is taken away with the earth still connected the conductor will not have any charge as it is connected to ground. Once the ground is removed the conductor will still be uncharged.
(b) Diagrams 1 to 4 show that the conductor will finally have a net negative charge.
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5. How could you determine the sign of the charge on a charged, isolated rod?
Easiest way is to use known charges, polystyrene rubbed on wool becomes negative, glass rubbed on silk becomes positive. If you bring a negatively charged polystyrene rod near the unknown rod: Attraction → unknown is positive Repulsion → unknown is negative
6. (a) A positively charged glass rod attracts an object suspended by a nonconducting
thread. Can we conclude that the object is negatively charged? (b) A positively charged glass rod repels a similarly suspended object. Can we
conclude that this object is positively charged?
Ans: (a) No. The object could be negatively charged but an uncharged object can still be attracted. See explanation for question 1.
(b) Yes. Repulsion can only occur when there are like charges so the object must be positive.
7. An electron (charge = -e) circulates around a helium nucleus (charge = +2e) in a helium atom. Which particle exerts the larger force on the other?
The forces are equal in magnitude – Newton’s Third law.
8. What would be the electrostatic force between two 1.00 C charges separated by a distance of (a) 1.00 m and (b) 1.00 km if such a configuration could be set up?
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9. A charge of +3.00 x 10-6 C is 120 mm distant from a second charge of-1.50 x 10-6 C. Calculate the magnitude of the force on each charge.
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Note that as the charges are opposite in sign the force is attractive however this in not asked for in the question.
10. What must be the distance between point charge q1 = 26.0 µC and point charge q2 = -47.0 µC in order that the electrostatic force between them have a magnitude of 5.70 N?
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11. The diagram shows two charges, ql and q2, held a fixed distance d apart. (a) What is the magnitude of the electrostatic force that acts on ql?
Assume that q1 = q2 = 20.0 µC and d = 1.50 m (b) A third charge q3 = 20.µC is brought in and placed as shown.
What now is the magnitude of the electrostatic force on ql?
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(b) Force on q1 due to q2 = 1.6 N Force on q1 due to q3 = 1.6 N (Q and r are the same) The vector diagram shows the components of the force:
F12 = 1.6 N F13 = 1.6 N F13x = -1.6 cos 30 = -1.39 N F13y = 1.6 sin 30 = 0.8 N q1 = 20 µC
Total force on q1 is: Fx = -1.39 N Fy = 1.6 + 0.8 = 2.4 N
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12. Two fixed charges, +1.0 µC, and -3.0 µC, are 100 mm apart. Where can a third charge be located so that no net electrostatic force acts on it?
Q1 = 1 µC = 1 x 10-6 C Q2 = -3 µC = -3 x 10-6 C q can have any value (+ or -) r = 100 mm = 0.1 m
Charge q, whether + or -, can only be placed to the left of Q1 as this is the only point where the forces can cancel.
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14. How many electrons must be removed from a neutral metal sphere to give it a net charge of +1 µC?
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13. Charges of +1 C and -2 C are placed 10 mm apart. What is the force acting between them? Is the force attractive or repulsive?
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15. Given that k = 9×109 N.m2/C2, find the repulsive force between two electrons spaced 1 nm apart.
Q = e = 1.6×10-19 Cr = 1 nm = 10-9 m
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16. For the electrons in question 15, what initial acceleration will these electrons experience if there are no other forces present?
From Newton’s Second Law: F = ma a = F/m = (2.3×10-10)/(9.1×10-31) = 2.5×1020 m/s2
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The electric field is defined as the force on a small charge, divided by the magnitude of the charge:
21-6 The Electric Field
Force exerted by charge Q on a small test charge, q, placed at points A, B, and C
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21-6 The Electric Field
An electric field surrounds every charge.
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For a point charge:
21-6 The Electric Field
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Force on a point charge in an electric field:
21-6 The Electric Field
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21-6 The Electric FieldExample 21-5: Photocopy machine.
A photocopy machine works by arranging positive charges (in the pattern to be copied) on the surface of a drum, then gently sprinkling negatively charged dry toner (ink) particles onto the drum. The toner particles temporarily stick to the pattern on the drum and are later transferred to paper and “melted” to produce the copy. Suppose each toner particle has a mass of 9.0 x 10-16 kg and carries an average of 20 extra electrons to provide an electric charge. Assuming that the electric force on a toner particle must exceed twice its weight in order to ensure sufficient attraction, compute the required electric field strength near the surface of the drum.
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21-6 The Electric FieldExample 21-5: Photocopy machine.
Mass of each toner particle = 9.0 x 10-16 kg and has an average of 20 extra electrons to provide an electric charge.
Assuming electric force on a toner particle must exceed twice its weight in order to ensure sufficient attraction, compute the required electric field strength near the surface of the drum.
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21-6 The Electric Field
Example 21-6: Electric field of a single point charge.
Calculate the magnitude and direction of the electric field at a point P which is 30 cm to the right of a point charge Q = -3.0 x 10-6 C.
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21-6 The Electric Field
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Copyright © 2009 Pearson Education, Inc.
Example 21-7: E at a point between two charges.Two point charges are separated by a distance of 10.0 cm. One has a charge of -25 μC and the other +50 μC.
(a) Determine the direction and magnitude of the electric field at a point P between the two charges that is 2.0 cm from the negative charge.
(b) If an electron (mass = 9.11 x 10-31 kg) is placed at rest at P and then released, what will be its initial acceleration (direction and magnitude)?
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Example 21-7: E at a point between two charges.(a) Determine the direction and magnitude of the electric
field at a point P between the two charges that is 2.0 cm from the negative charge.
left toN/C 106.321
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Copyright © 2009 Pearson Education, Inc.
(b) If an electron (mass = 9.11 x 10-31 kg) is placed at rest at P and then released, what will be its initial acceleration (direction and magnitude)?
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21-6 The Electric Field
Example 21-8: above two point charges.
Calculate the total electric field (a) at point A and (b) at point B in the figure due to both charges, Q1
and Q2.
E
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Problem solving in electrostatics: electric forces and electric fields
1. Draw a diagram; show all charges, with signs, and electric fields and forces with directions.
2. Calculate forces using Coulomb’s law.
3. Add forces vectorially to get result.
4. Check your answer!
21-6 The Electric Field
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Total electric field point A
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Copyright © 2009 Pearson Education, Inc.
Total electric field point B
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21-7 Electric Field Calculations for Continuous Charge Distributions
A continuous distribution of charge may be treated as a succession of infinitesimal (point) charges. The total field is then the integral of the infinitesimal fields due to each bit of charge:
Remember that the electric field is a vector; you will need a separate integral for each component.
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21-7 Electric Field Calculations for Continuous Charge Distributions
Example 21-9: A ring of charge.
A thin, ring-shaped object of radius a holds a total charge +Q distributed uniformly around it. Determine the electric field at a point P on its axis, a distance x from the center. Let λ be the charge per unit length (C/m).
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Example 21-9: A ring of charge.
Because P is on the axis, the transverse components of E (dE) must add to zero, by symmetry.
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21-7 Electric Field Calculations for Continuous Charge Distributions
Conceptual Example 21-10: Charge at the center of a ring.
Imagine a small positive charge placed at the center of a nonconducting ring carrying a uniformly distributed negative charge. Is the positive charge in equilibrium if it is displaced slightly from the center along the axis of the ring, and if so is it stable? What if the small charge is negative? Neglect gravity, as it is much smaller than the electrostatic forces.
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Conceptual Example 21-10: Charge at the center of a ring.
The positive charge is in equilibrium because there is no net force on it, by symmetry. If the positive charge moves away from the center of the ring along the axis in either direction, the net force will be back towards the center of the ring and so the charge is in stable equilibrium. A negative charge at the center of the ring would feel no net force, but is in unstable equilibrium because if it moved along the ring's axis, the net force would be away from the ring and the charge would be pushed farther away.
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21-7 Electric Field Calculations for Continuous Charge Distributions
Example 21-11: Long line of charge.
Determine the magnitude of the electric field at any point P a distance x from a very long line (a wire, say) of uniformly distributed charge. Assume x is much smaller than the length of the wire, and let λ be the charge per unit length (C/m).
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Example 21-11: Long line of charge.
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Copyright © 2009 Pearson Education, Inc.
Example 21-11:
Long line of charge.
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21-7 Electric Field Calculations for Continuous Charge Distributions
Example 21-12: Uniformly charged disk.
Charge is distributed uniformly over a thin circular disk of radius R. The charge per unit area (C/m2) is σ. Calculate the electric field at a point P on the axis of the disk, a distance zabove its center.
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Example 21-12: Uniformly charged disk.
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Example 21-12: Uniformly charged disk.
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21-7 Electric Field Calculations for Continuous Charge Distributions
In the previous example, if we are very close to the disk (that is, if z << R), the electric field is:
This is the field due to an infinite plane of charge.
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21-7 Electric Field Calculations for Continuous Charge Distributions
Example 21-13: Two parallel plates.
Determine the electric field between two large parallel plates or sheets, which are very thin and are separated by a distance dwhich is small compared to their height and width. One plate carries a uniform surface charge density σ and the other carries a uniform surface charge density -σ as shown (the plates extend upward and downward beyond the part shown).
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Example 21-13: Two parallel plates.
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The electric field can be represented by field lines. These lines start on a positive charge and end on a negative charge.
21-8 Field Lines
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The number of field lines starting (ending) on a positive (negative) charge is proportional to the magnitude of the charge.
The electric field is stronger where the field lines are closer together.
21-8 Field Lines
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Electric dipole: two equal charges, opposite in sign:21-8 Field Lines
Note that the tangent to a field line at any point P gives the direction of the electric field at Pand the direction of the force acting on a positive charge placed at P.
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21-8 Field Lines – Other Examples
Opposite charges Unequal charges
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The electric field between two closely spaced, oppositely charged parallel plates is constant.
21-8 Field Lines
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Summary of field lines:
1.Field lines indicate the direction of the field; the field is tangent to the line.
2.The magnitude of the field is proportional to the density of the lines.
3.Field lines start on positive charges and end on negative charges; the number is proportional to the magnitude of the charge.
21-8 Field Lines
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The static electric field inside a conductor is zero – if it were not, the charges would move.(Proof of this is given in Chapter 22 Gauss’s Law.Check this if you like but Gauss’s Law is not in course)
The net charge on a conductor resides on its outer surface.
21-9 Electric Fields and Conductors
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The electric field is perpendicular to the surface of a conductor – again, if it were not, charges would move.
21-9 Electric Fields and Conductors
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Copyright © 2009 Pearson Education, Inc.
21-9 Electric Fields and Conductors
If the electric field at the surface of a conductor had a component parallel to the surface E||, the latter would accelerate electrons into motion. In the static case, E|| must be zero, and the electric field must be perpendicular to the conductor’s surface: E = E┴
Copyright © 2009 Pearson Education, Inc.
21-9 Electric Fields and ConductorsConceptual Example 21-14: Shielding, and safety in a storm.
A neutral hollow metal box is placed between two parallel charged plates as shown. What is the field like inside the box?
The field inside the box is zero. This is why it can be relatively safe to be inside an automobile during an electrical storm.
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Copyright © 2009 Pearson Education, Inc.
21-10 Motion of a Charged Particle in an Electric Field
The force on an object of charge q in an electric field is given by:
= q
Therefore, if we know the mass and charge of a particle, we can describe its subsequent motion in an electric field.
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Copyright © 2009 Pearson Education, Inc.
21-10 Motion of a Charged Particle in an Electric Field
Example 21-15: Electron accelerated by electric field.
An electron (mass m = 9.11 x 10-31 kg) is accelerated in the uniform field (E = 2.0 x 104 N/C) between two parallel charged plates. The separation of the plates is 1.5 cm. The electron is accelerated from rest near the negative plate and passes through a tiny hole in the positive plate. (a) With what speed does it leave the hole? (b) Show that the gravitational force can be ignored. Assume the hole is so small that it does not affect the uniform field between the plates.
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Copyright © 2009 Pearson Education, Inc.
Example 21-15: Electron accelerated by electric field.
(a) With what speed does it leave the hole?
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Copyright © 2009 Pearson Education, Inc.
Example 21-15: Electron accelerated by electric field.(b) Show that the gravitational force can be ignored.
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Copyright © 2009 Pearson Education, Inc.
21-10 Motion of a Charged Particle in an Electric Field
Example 21-16: Electron moving perpendicular to .
Suppose an electron traveling with speed v0 = 1.0 x 107 m/s enters a uniform electric field , which is at right angles to v0 as shown. Describe its motion by giving the equation of its path while in the electric field. Ignore gravity.
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E
Copyright © 2009 Pearson Education, Inc.
21-10 Motion of a Charged Particle in an Electric Field
Example 21-16: Electron moving perpendicular to .E
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Copyright © 2009 Pearson Education, Inc.
• Two kinds of electric charge – positive and negative.
• Charge is conserved.
• Charge on electron:
e = 1.602 x 10-19 C.
• Conductors: electrons free to move.
• Insulators: nonconductors.
Summary of Chapter 21
Copyright © 2009 Pearson Education, Inc.
• Charge is quantized in units of e.
• Objects can be charged by conduction or induction.
• Coulomb’s law:
•Electric field is force per unit charge:
Summary of Chapter 21
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Copyright © 2009 Pearson Education, Inc.
• Electric field of a point charge:
• Electric field can be represented by electric
field lines.
• Static electric field inside conductor is zero; surface field is perpendicular to surface.
Summary of Chapter 21
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