Capacitance 電容 (Ch. 25)1. A capacitor 電容器 is a device in
which electrical energy is stored.
2. e.g. the batteries in a camera store energy in the photoflash unit by charging a capacitor.
3. once the capacitor is charged, it can supply energy at a much greater rate when the photoflash unit is triggered -- enough to allow the unit to emit a burst of bright light.
4. the capability of how much charge a capacitor can store is called capacitance.
1. A capacitor can be any two isolated conductors of any shapes.
2. but for simplicity, we shall first consider two separated parallel plates.
3. The capacitance is defined by:
CVq • C depends on the
geometry of the capacitor.
unit: 1 F (farad)=C/V
1. simplest way to charge a capacitor is to use a battery.
2. opposite charges begin to accumulate on the plates until the potential V between the plates equals to the potential difference between the battery’s terminals.
3. No more current flow when C is fully charged.
4. Larger C means more charges Q can be stored for the same V.
Calculating the capacitance
1. Once we know the geometry of the capacitor, one may calculating its capacitance.
2. here we start with the simplest parallel-plate capacitor.
3. Gauss’s law will be used.
• Assume there are charges q on either plate, the electric field E between the plates produced by the charges is given by:
• note that there is no field inside the plate, and E is parallel to the dA, so the total flux through the Gaussian surface is:
where A is the area of the plate.
If d is small enough and if we are looking at the point away from the edges, the field E can be considered as uniform.
The potential difference between the plates are now:
• therefore the capacitance is:
i.e., a larger capacitance needs a larger area A but smaller separation d.
Cylindrical capacitor
• this type of capacitance can be calculated similarly, but now the field E is no longer uniform and changes as r.
• From Gauss’ law:
note that there is no flux passes through the other two surfaces, because E and dA is perpendicular.
Now, the electric E is :
a function of r.
The potential difference V is:
As a result, the capacitance is:
A spherical capacitor
The above calculation can be easily modified to the case of spherical capacitor:
Gauss’ law
An isolated sphere
One can easily generalize the previous result of spherical capacitor to an isolated charged sphere.
When the radius of the outer sphere b is very large, or becomes infinite, the capacitance is now:
Here R is the radius of the sphere, i.e. a=R.
(a) The capacitance is :V
qC
(b) The capacitance depends on the geometry of the system only. So it remains the same.
(c) the potential difference is: C
qV
Capacitors in parallel 平行 and in series 串聯
Capacitors in parallel1. the potential difference V is
the same on each capacitors.
2. so the charge on each capacitors is:
3. one can consider the capacitors as an equivalent capacitor Ceq with charge q=q1+q2+q3 .
VCVCCCq
VCVCVCqqqq
eq
)( 321
321321
4. so or in general
Capacitors in series1. all capacitors have the same charge q.
2. the total potential difference is
321
111
CCCC
charge on the system is CVq
This is the charge stored in C3 and in C12. So the potential difference between AB is VAB=q/C12, or 21 CC
CVVAB
Now, the charge on C1 is then
321
3111 CCC
VCCVCq AB
Energy stored in an electric field
Therefore to charge a capacitor, the total work is
This is the energy stored in a capacitor, or can be viewed as the energy stored in the electric field.
Work done required to move a charge dq’ across a potential difference V’ is
Energy density:
energy per unit volume:
This in fact applies to all electric fields but not just the one produced by capacitors.
Capacitor with a dielectric 介電質 1. The capacitance of a capacitor can be changed if a dielectric
is placed between the plates.
2. In this example, the capacitance is increased: for the same potential difference V, the capacitor holds more charges; for the amount of charge q, V is smaller.
1. The capacitance is increased by a factor κ, which is called the dielectric constant 介質常數 .
airCC
2. The dielectric constant of vacuum is by definition equal to one. Since air is mostly empty space, its dielectric constant is only slightly greater than one.
3. Every dielectric has a characteristic dielectric strength, which is the maximum value of the electric field that it can tolerate without breakdown.
In other words, the permittivity constant 介電常數 is modified to
for parallel plates capacitor with a dielectric:
d
AC 0
0
Thus, the electric field produced by a point charge inside the dielectric is now:
The field outside a conducing plate is then:
Note that κis larger than 1 and hence the electric field is reduced inside a dielectric.
before the slab is inserted:
after the slab is inserted:
The potential energy is reduced, but where does it go?
If there is no friction, the slab would oscillate back and forth between the plates with a kinetic energy
(a) V is fixed by the battery, so remains unchanged.
(b) the capacitance is increased.
(c) the charge is then increased.
(d) the potential energy U=CV2/2 is increased too.
Dielectrics:
Polar dielectrics: some materials, like water, have permanent electric dipole moments. When an electric field is applied, the molecules will try to align along the field direction. This alignment produced an electric field oppose to the applied field . Therefore a the dielectric reduces the applied electric field.
Nonpolar dielectrics:
Even a nonpolar dielectric have no permanent dipole moments, an applied field will polarize the molecule in some extents. The result is again a smaller field opposed to the applied field.
Note that there are induced charges on the surface on the dielectric.
Dielectrics and Gauss’ law
We have learned the Gauss’ law applied in a vacuum, it is straightforward to generalize it to a dielectric:
The induced charge on the dielectric will reduce the net charge inside the Gaussian surface:
Since we know that the original field is weaken by a factor of κ, so
or 1'
q
therefore, one can rewrite the Gauss’ law as:
Again, this can be generally applied to all other cases.
Also, now q represents only the free charges.
1For Gaussian surface I:
For Gaussian surface II:
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