Electric(Potential · Afew(answers Why(does(this(even(matter?(Please(go(over(in(detail,(it(kinda...
Transcript of Electric(Potential · Afew(answers Why(does(this(even(matter?(Please(go(over(in(detail,(it(kinda...
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Electric PotentialEquipotentials and Energy
Phys 122 Lecture 8G. Rybka
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Your Thoughts• Nervousness about the midterm
• Confusion about Potential
• Some like the material!
I would like to have a final review of all the concepts that we should know for the midterm. I'm having a lot of trouble with the homework and do not think those questions are very similar to what we do in class, so if that's what the midterm is like I think we need to do more mathematical examples in class.
I am really lost on all of this to be honest
I'm having trouble understanding what Electric Potential actually is conceptually.
These are yummy.I love potential energy. I think it is fascinating. The world is amazing and physics is everything.
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A few answersWhy does this even matter? Please go over in detail, it kinda didn't resonate with practical value.
This is the first pre-lecture that really confused me. What was the deal with the hill thing?
don't feel confident in my understanding of the relationship of E and V. Particularly calculating these. If we go into gradients of V, I will not be a happy camper...
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The Big IdeaElectric potential ENERGY of charge q in an electric field:
∫ ∫ ⋅−=⋅−=−=Δ →→
b
a
b
ababa ldEqldFWU
!!!!
∫ ⋅−=−
=Δ
≡Δ →→→
b
a
bababa ldE
qW
qUV
!!
New quantity: Electric potential (property of the space) is the Potential ENERGY per unit of charge
If we know E, we can get V
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The CheckPoint had an “easy” E field
∫ ⋅−=Δ →
B
ABA ldEV
!!
A)B)C)D)
We just learned that
0=E!
0=Δ →BAV V is constant!
Suppose the electric field is zero in a certain region of space. Which of the following statements best describes the electric potential in this region?
The Change in V is 0, the actual value is a constant
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Potential from charged spherical conducting shell
• E Fields (from Gauss' Law)
• Potentials• r > R:
• r < R:
R
R
Q4πε0 R
R r
VQ4πε0 r
E = 0• r < R:
E = 1
4 πε0
Qr 2 • r > R:
We just learned V = constant when E = 0
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a b
cunchargedconductor
sphere withUniform charge Total = Q
More challenging …Calculate the potential V(r) at x
• Work from outside in …
• Determine E(r) everywhere
• Determine ΔV for each region by integration
III
IIIIVr
V=0 at r=�...
Yes, yes, a mess !
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a b
c
IIIIIIIV
V vs Radius
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ClickerA point charge Q is fixed at the center of an uncharged conducting spherical shell of inner radius a and outer radius b.
– What is the value of the potential Va at the inner surface of the spherical shell?
(c)(b)(a)
The potential is given by:
E outside the spherical shell
Eout
E=0
E inside the spherical shell: E = 0
a
b
Q
1A
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E from VSince we can get V from integrating E
• Expressed as a vector, E is µ gradient of V
• Cartesian coords:
• Spherical coords:
∫ ⋅−=Δ →
b
aba ldEV
!!
We should get E by differentiating V
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E from V: a simple Example• Consider the following electric potential:
• What electric field does this describe?
... expressing this as a vector:
“Can we please go over the "gradient" more?”
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What is going on ?• We are finding the SLOPE in the potential function
• The sign is telling us which way E increases
The SP folks like this picture of a potential
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How do we get E from V?
VE ∇−=!"
B: “ The slope of the electric potential is the magnitude of the electric “
CheckPoint Review
dxVEx∂
−= Look at slopes!
At which point is the magnitude of the E-field greatest?
The electric potential in a certain region is plotted in the following graph
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ABCD
Clicker of a Checkpoint
How do we get E fromV?
VE ∇−=!"
dxVEx∂
−= Look at slopes!
A B C D E = none of these
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Equipotentials
• GENERAL PROPERTY:– The Electric Field is always perpendicular to an Equipotential Surface.
• Why??
Dipole Equipotentials
Defined as: The locus of points with the same potential. • Example: for a point charge, the equipotentials are spheres centered on the charge.
The gradient ( ) says E is in the direction of max rate of change.Along an equipotential surface there is NO change in V so E along this surface does not changeà E must be normal to the equipotential surface
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Equipotential Example• Field lines more closely spaced near end with most curvature .
• Field lines ⊥ to surface near the surface (since surface is equipotential).
• Equipotentialshave similar shape as surface near the surface.
• Equipotentialswill look more circular (spherical) at large r.
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ABCD
“The electric field lines are the least dense at D “
Let’s look at this series of checkpointsThe field-line representation of the E-field in a certain region in space is shown below. The dashed lines represent equipotential lines.
At which point in space is the E-field the weakest?
Okay, so far, so good J
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ABCD
A)B)C)D)
What ?Compare the work done moving a negative charge from A to B and from C to D. Which one requires more work?
Problem !
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ABCD
What are these?
ELECTRIC FIELD LINES!
What are these?
EQUIPOTENTIALS!What is the sign of WAC = work done by E field to move negative charge from A to C ?
A) WAC < 0 B) WAC = 0 C) WAC > 0
A and C are on the same equipotentialEquipotentialsare perpendicular to the E field: No work is done along an equipotential
Now a Clicker
WAC = 0
First a Hint
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ABCD
A)B)C)D)
Back to the Checkpoint …Compare the work done moving a negative charge from A to B and from C to D. Which one requires more work?
Problem !
• We just found: WAC = 0; • àA&C at same potential• Similarly: B&D at same potential
• Look at path from A to B and consider change in potential• Look at path from C to D and consider change in potential
• THEY ARE THE SAME so Work done is the same.
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ABCD
A answer: “E field weak at d“B answer: “Moving the charge from A to D crosses more equipotential lines, so it requires more work. C answer: “Since B and D are on the same equipotential line, the change in potential energy (and therefore the work required) between A and either point is the same.”
Another one … now, A to B or D
A)B)C)D)
Compare the work done moving a negative charge from A to B and fromA to D. Which one requires more work?
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The Bottom Line
allows us to calculate the potential function V everywhere (keep in mind, we often define VA = 0 at some convenient place)
allows us to calculate the electric field E everywhere
Þ
• Units for Potential! 1 Joule/Coul = 1 VOLT
If we know the electric field E everywhere,
If we know the potential function V everywhere,