electric fields and capacitors
DESCRIPTION
Electric Fields and Capacitors. The basis of Electric storage. A Learning Summary. Two objects are just resolved when the central diffraction maximum of one object is at the first minimum of the other . (Rayleigh’s criterion) As before, q is approximately tan q = y / L - PowerPoint PPT PresentationTRANSCRIPT
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Electric Fields and Capacitors
The basis of Electric storage
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• Two objects are just resolved when the central diffraction maximum of one object is at the first minimum of the other. (Rayleigh’s criterion)
As before, is approximately tan = y/L Circular aperture has diameter d
A Learning Summary
ddR
22.122.1
sin 1
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What type of forces could act on e-?
Gravity, if . . .• another mass is around.
Electricity, if . . .• another charged object is around.
Magnetism, if . . .• the e- is in a magnetic field
The weak nuclear force, if . . .• any other fermion is around
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Gravity’s force between e- and p+
Force between two objects due to gravity:
m1 = me = 9.11 E-31 kgm2 = mproton = 1.67 E-27 kgr = 1 nm = 10-9 mF = 1.01 E-49 N
221
r
mmGF
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Electrical force between e- and p+
Force between two objects due to Coulomb (electric) attraction:
q1 = qe = 1.602 E-19 Cq2 = qproton = 1.602 E-19 Cr = 1 nm = 10-9 mF = 2.31 E-10 N
221
r
qqkF
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Nuclear force between e- and p+
Force between two objects due to the weak nuclear force:
s = 2mc2E = 1 GeV2 = 2.5 E-20 J2
mW = 1.42 E-25 kgr = 1 nm = 10-9 mGF = 4.52 E 14 J-2
F < 1 E -100,000 N
hcrmF
WseGF 2/
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Comparing forces between e- and p+
Electric: F= 2.31 E-10 NGravity: F= 1.01 E-49 NNuclear: F < 1 E -100,000 NIf I had 1% more electrons than protons, and
I stood an arm’s length away from a similarly imbalanced person, the force between us would be great enough to lift a weight the size of . . .
• The earth!
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How can a force act at a distance?
If I took my electron away from the proton and brought a positron (positive e) near the proton, the positron would . . .
• accelerate away from the protonSo, does my proton exert a force if no one is
around to feel it?• Force, no. But we can define an electric
field which describes the force a charge would feel if it came near the proton
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How can a force act at a distance?
A charge creates an electric field that fills space, whether or not any other charge is around to feel its effects!
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Make Predictions for the Activity, then Answer Questions 1-7 of the Activity
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What’s a Field?
Electric field E = F/q, where q is the charge feeling the force
Since forces obey the law of linear superposition (i.e., they add), electric fields add too!
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What does a “field” look like?
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Finish the Activity, working as far as you can in the time allowed
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Charges in Conductors Electric fields are created when positive charges
and negative charges are separated A uniform electric field existing over a region sets
up a potential difference between points in that region: V=Ex, where x is the distance along a field line.
If I apply a potential difference across a conducting object (including semi-conductors), charges experience a force, and charge carriers will flow until the potential difference is removed.
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What if charge can’t flow? Consider charge separated by two metal
plates– A potential difference exists between the plates– An electric field exists between the plates,
pointing from positive plate to negative plate– No current can flow
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Introducing, . . . The Capacitor
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Introducing, . . . Capacitance
The battery provides the work needed to move the charges and increase their potential energy
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What determines capacitance?
C = 0 A/d
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More about capacitors
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More about capacitorsU = Vq = Ve
1 eV = 1.602 x 10-19 J
= energy to move electron through 1 volt