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Chapter 26 HW: P: 10,18,21,29,33,48, 51,53,54,68
Capacitance
and
Dielectrics
Capacitors
Capacitors are devices that store electric charge and energyExamples of where capacitors are used include:
radio receiversfilters in power suppliesenergy-storing devices in electronic flashes
Some Uses of Capacitors
DefibrillatorsWhen fibrillation occurs, the heart produces a rapid, irregular pattern of beatsA fast discharge of electrical energy through the heart can return the organ to its normal beat pattern
In general, capacitors act as energy reservoirs that can be slowly charged and then discharged quickly to provide large amounts of energy in a short pulse
CapacitanceThe capacitance, C, of a capacitor is defined as the ratio of the magnitude of the charge on either conductor to the potential difference between the conductors
The capacitance is a measure of the capacitor’s ability to store chargeThe SI unit of capacitance is the farad (F)
QCV
=Δ
CapacitanceThe capacitance is proportional to the area of its plates and inversely proportional to the distance between the plates
QCV
=Δ
( )= = = = =
Δ /o
o
o
ε AQ Q Q QC σV Ed Q ε A d ddε
= oε ACd
A capacitor consists of two conductorsThese conductors are called platesWhen the conductor is charged, the plates carry charges of equal magnitude and opposite directions
A potential difference exists between the plates due to the chargeCapacitance will always be a positive quantityThe capacitance of a given capacitor is constantThe farad is a large unit, typically you will see microfarads (μF) and picofarads (pF)A capacitor stores electrical energy
Makeup of a Capacitor
Parallel Plate Assumptions
The assumption that the electric field is uniform is valid in the central region, but not at the ends of the platesIf the separation between the plates is small compared with the length of the plates, the effect of the non-uniform field can be ignoredThe charge density on the plates is σ = Q/A
A is the area of each plate, which are equalQ is the charge on each plate, equal with opposite signs
Charging a Parallel Plate Capacitor
Each plate is connected to a terminal of the batteryIf the capacitor is initially uncharged, the battery establishes an electric field in the connecting wires
Active Figure 26.4
AF_2604.html
Energy in a CapacitorConsider the circuit to be a systemBefore the switch is closed, the energy is stored as chemical energy in the batteryWhen the switch is closed, the energy is transformed from chemical to electric potential energy
Energy Stored in a CapacitorAssume the capacitor is being charged and, at some point, has a charge q on itThe work needed to transfer a charge from one plate to the other is
The total work required is
The work done in charging the capacitor appears as electric potential energy U:
qdW Vdq dqC
= Δ =
2
0 2Q q QW dq
C C= =∫
221 1 ( )
2 2 2QU Q V C VC
= = Δ = Δ
This applies to a capacitor of any geometryThe energy stored increases as the charge increases and as the potential difference increasesIn practice, there is a maximum voltage before discharge occurs between the platesThe energy can be considered to be stored in the electric field For a parallel-plate capacitor, the energy can be expressed in terms of the field as U = ½ (εoAd)E2
It can also be expressed in terms of the energy density (energy per unit volume)uE = ½ εoE2
221 1 ( )
2 2 2QU Q V C VC
= = Δ = Δ
Energy Stored in a Capacitor
DielectricsA dieletric is an insulator that increases the capacitance.
Reduced E field prevents breakdown & discharge between plates.
0 ACd
κε=
DielectricsThe dieletric constant is the ratio of the field magnitude without and with the dielectric.
Reduced E field prevents breakdown & discharge between plates.
~ 13.7
80
Air
Paper
Water
κκ
κ
=
=
0EE
κ =
DielectricsIf the field becomes too great, the dielectric breaks down
and becomes a conductor and the plates discharge.
Reduced E field prevents breakdown & discharge between plates.
Dielectric Breakdown of Air
ProblemWhat is the maximum voltage that can be sustainedbetween 2 parallel plates separated by 2.5 cm of dry air?Dry air supports max field strength of 3x 106 V/m .
V Ed=6(3 10 / )(.025 )x V m m=
47.5 10x V=
75kV=
More than this and the air breaks down and becomes a conductor. LIGHTENING!
The dieletric constant is the ratio of the net electric field magnitude without the dielectric,E0, and with the dielectric, E.
The dielectric reduces the net electric field and potential difference across the plates.
Reduced E field prevents breakdown & discharge between plates.
0EE
κ = 0 /E E κ=
Dielectrics – An Atomic ViewThe molecules that make up the dielectric are modeled as dipolesThe molecules are randomly oriented in the absence of an electric field
Dielectrics – An Atomic ViewAn external electric field is applied which produces a torque on the moleculesThe molecules partially align with the electric fieldThe degree of alignment of the molecules with the field depends inversely upon temperature and directly with the magnitude of the fieldThe degree of alignment of the molecules with the field depends on the polarization of the molecules.
0 0/E σ ε=
Polar vs. Nonpolar MoleculesMolecules are said to be polarized when a separation exists between the average position of the negative charges and the average position of the positive chargesPolar molecules are those in which this condition is always presentMolecules without a permanent polarization are called nonpolar molecules
Water MoleculesA water molecule is an example of a polar moleculeThe center of the negative charge is near the center of the oxygen atomThe x is the center of the positive charge distribution
The average positions of the positive and negative charges act as point chargesTherefore, polar molecules can be modeled as electric dipoles
Induced PolarizationA symmetrical molecule has no permanent polarization (a)Polarization can be induced by placing the molecule in an electric field (b)Induced polarization is the effect that predominates in most materials used as dielectrics in capacitorsInduced polar molecules can also be modeled as electric dipoles
Electric DipoleAn electric dipole consists of two charges of equal magnitude and opposite signsThe charges are separated by 2aThe electric dipole moment (p) is directed along the line joining the charges from –q to +qThe electric dipole moment has a magnitude of p = 2aq
Electric Dipole in an External E FieldEach charge has a force of F = Eq acting on itThe net force on the dipole is zeroThe forces produce a net torque on the dipole that makes it align with the external electric field.
The magnitude of the torque is:τ = 2(Fa sin θ) = 2Eqa sin θ = pE sin θ
The torque can also be expressed as the cross product of the moment and the field: τ = p x E
An external field can polarize the dielectric whether the molecules are polar or nonpolarThe charged edges of the dielectric act as a second pair of plates producing an induced electric field in the direction opposite the original electric field, thus reducing the net electric field in the dielectric:
Dielectrics – An Atomic View
0/ind indE σ ε=
0 0/E σ ε=
0 indE E E= − 0 /E E κ=
Dielectrics – An Atomic View
0/ind indE σ ε=
0 0/E σ ε=0 indE E E= −
0 0 0
indσσ σκε ε ε
= −
0 /E E κ=
1ind
κσ σκ−
=
1 indκ σ σ> → <
Induced Charge and Field
The electric field due to the plates is directed to the right and it polarizes the dielectricThe net effect on the dielectric is an induced surface charge that results in an induced electric fieldIf the dielectric were replaced with a conductor, the net field between the plates would be zero
0 indE E E= −
0C Cκ=
0 ACd
κε=
0 /V V κΔ = Δ
Circular Plates
(plate radius = 10 cm) ε0= 8.85x10 –12 Farad/m
Capacitance of a Cylindrical Capacitor
From Gauss’s Law, the field between the cylinders isE = 2keλ / rΔV = -2keλ ln (b/a)The capacitance becomes
( )= =
Δl
00 2 ln /e
QCV k b a ( )
≡≡ ≡= = =Δ
l0 2 ln /e
QC CV k b a
Coaxial Cable
Radio-grade flexible coaxial cable.A: outer plastic sheathB: copper screenC: inner dielectric insulatorD: copper core
Geometry of Some Capacitors
Capacitors in ParallelThe total charge is equal to the sum of the charges on the capacitors
Qtotal = Q1 + Q2The potential difference across the capacitors is the same
And each is equal to the voltage of the battery:
ΔV = ΔV1 = ΔV2
The capacitors can be replaced with one capacitor with a capacitance of Ceq
Qtotal = Q1 + Q2
Capacitors in Parallel
Essentially, the areas are combined
= Δtotal eqQ C V
Ceq = C1 + C2 + …
Δ = Δ + Δ1 2eqC V C V C V
Capacitors in SeriesWhen a battery is connected to the circuit, electrons are transferred from the left plate of C1 to the right plate of C2through the batteryAs this negative charge accumulates on the right plate of C2, an equivalent amount of negative charge is removed from the left plate of C2, leaving it with an excess positive chargeAll of the right plates gain charges of –Q and all the left plates have charges of +Q thus:
QCV
=Δ
= =1 2Series: Q Q Q
Capacitors in SeriesThe potential differences add up to the battery voltageΔV = V1 + V2 + …
The equivalent capacitance of a series combination is always less than any individual capacitor in the combination
1 2
1 1 1
eqC C C= + +K
Δ =eq
QVC
Capacitor Summary
Δ = Δ + Δ + ⋅ ⋅ ⋅
= =
= + +K
1 2
1 2
1 2
Capacitors in Series:
Q1 1 1eq
V V VQ Q
C C C
Δ = Δ = Δ
= +
= + +K
1 2
1 2
1 2
Capacitors in Parallel:
tot
eq
V V VQ Q QC C C
Equivalent Capacitance
Fig P26-22, p.824
P22. Three capacitors are connected to a battery as shown in Figure P26.22. Theircapacitances are C1 = 3C, C2 = C, and C3 = 5C. (a) What is the equivalentcapacitance of this set of capacitors? (b) State the ranking of the capacitorsaccording to the charge they store, from largest to smallest. (c) Rank thecapacitors according to the potential differences across them, from largest tosmallest.
Δ = Δ = Δ= +
= + +K
1 2
1 2
1 2
Capacitors in Parallel:
tot
eq
V V VQ Q QC C C
Δ = Δ + Δ + ⋅ ⋅ ⋅= =
= + +K
1 2
1 2
1 2
Capacitors in Series:
Q1 1 1
eq
V V VQ Q
C C C
Fig P26-27, p.824
( )( )
1
1
2
1
1 1 3.33 F5.00 10.02 3.33 2.00 8.66 F
2 10.0 20.0 F
1 1 6.04 F8.66 20.0
s
p
p
eq
C
C
C
C
μ
μ
μ
μ
−
−
⎛ ⎞= + =⎜ ⎟⎝ ⎠
= + =
= =
⎛ ⎞= + =⎜ ⎟⎝ ⎠
27. Find the equivalent capacitance between points a and b for the group ofcapacitors connected as shown in Figure P26.27. Take C1 = 5.00 μF, C2 = 10.0 μF,and C3 = 2.00 μF.
You Try:
P26.72 Assume a potential difference across a and b, and notice that the potential differenceacross the 8.00 Fμ capacitor must be zero by symmetry. Then the equivalent capacitance can bedetermined from the following circuit:
⇒
⇒
FIG. P26.72
P26.75 By symmetry, the potential difference across 3C is zero, so the circuit reduces to
11 1 8 42 4 6 3eqC C CC C
−⎛ ⎞= + = =⎜ ⎟⎝ ⎠
.
You Try:
Variable CapacitorsVariable capacitors consist of two interwoven sets of metallic platesOne plate is fixed and the other is movableThese capacitors generally vary between 10 and 500 pFUsed in radio tuning circuits