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15. 7. 20031 I-7 Electric Energy Storage. Dielectrics.

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Presentation on theme: "15. 7. 20031 I-7 Electric Energy Storage. Dielectrics."— Presentation transcript:

1 15. 7. 20031 I-7 Electric Energy Storage. Dielectrics.

2 15. 7. 20032 Main Topics Electric Energy Storage. Inserting a Conductor into a Capacitor. Inserting a Dielectric into a Capacitor. Microscopic Description of Dielectrics Concluding Remarks to Electrostatics.

3 15. 7. 20033 Electric Energy Storage I We have to do work to charge a capacitor. This work is stored as a potential energy and all (if neglecting the losses) can be used at later time (e.g. faster to gain power). If we do any changes to a charged capacitor we do or the field does work. It has to be distinguished whether the power source is connected or not during the change.

4 15. 7. 20034 Electric Energy Storage II Charging a capacitor means to take a positive charge from the negative electrode and move it to the positive electrode or to take a negative charge from the positive electrode and move it to the negative electrode. In both cases (we can take any path) we are doing work against the field and thereby increasing its potential energy. Charge should not physically pass through the gap between the electrodes of the capacitor!

5 15. 7. 20035 Electric Energy Storage III A capacitor with the capacitance C charged by the charge Q or to the voltage V has the energy: U p = Q 2 /2C = CV 2 /2 = QV/2 The factor ½ in the formulas reveals higher complexity then one might expect. By moving a charge between the electrodes we also change Q, V so we must integrate.integrate

6 15. 7. 20036 Electric Energy Storage IV The energy density Let us have a parallel plate capacitor A,d,C, charged to some voltage V: Since Ad is volume of the capacitor we can treat  0 E 2 /2 as the density of (potential) energy In uniform field each volume contains the same energy.

7 15. 7. 20037 Electric Energy Storage V In non-uniform fields energy has to be integrated over volume elements where E is (approximately) constant. In the case of charged sphere these volumes would be concentric spherical shells ( r > r i ) :

8 15. 7. 20038 Electric Energy Storage VI Integrating from some R  r i to infinity we get : For R = r i we get the same energy as from a formula for spherical “capacitor”. We can also see, for instance, that half of the total energy is in the interval r i < r < 2r i or 99% of the total energy would be in the interval r i < r < 99r i

9 15. 7. 20039 Inserting a Conductor Into a Capacitor I Let us insert a conductive slab of area A and thickness  < d into the gap between the plates of a parallel plate capacitor A,d,  0, . The conductive slab contains enough free charge to form on its edges a charge density  p equal to the original . So the original field is exactly compensated in the slab. Effectively the gap changed to d - .

10 15. 7. 200310 A Guiz Inserting a conductive slab of area A and thickness  < d into the gap between the plates of a parallel plate capacitor A,d,  0,  will increase its capacitance. Where should we put the slab to maximize the capacitance ? A) next to one of the plates. B) to the plane of symmetry. C) it doesn’t matter.

11 15. 7. 200311 C: It doesn’t matter ! Let us insert the slab some distance x from the left plate. Then we effectively have a serial connection of two capacitors, both with the same A. One has the gap x and the other d-x- . So we have:

12 15. 7. 200312 Inserting a Conductor Into a Capacitor II The capacitance has increased. In the case of disconnected power source the charge is conserved and the energy decreases – the slab would be pulled in. In the case of connected power source the voltage is conserved and the energy increases – we do work to push the slab in and also the source does work to put some more charge in.

13 15. 7. 200313 Inserting a Dielectric Into a Capacitor I Let us charge a capacitor, disconnect it from the power source and measure the voltage across it. When we insert a dielectric slab we shall notice that The voltage has dropped by a ratio K = V 0 /V The slab was pulled in by the field We call K the dielectric constant or the relative permitivity (  r ) of the dielectric.  r depends on various qualities T, f!

14 15. 7. 200314 Inserting a Dielectric Into a Capacitor II What has happened : Since the inserted plate is a dielectric it contains no free charges to form a charge density on its edges, which would be sufficient to compensate the original field. But the field orientates electric dipoles. That effectively leads to induced surface charge densities which weaken the original field and thereby increase the capacitance.

15 15. 7. 200315 Inserting a Dielectric Into a Capacitor III The field orientates electric dipoles their charges compensate everywhere except on the edges next to the capacitor plates, where some charge density  p <  remains. The field in the dielectric is then a superposition of the field generated by the original  and the induced  p charge densities. In the case of homogeneous polarization the induced charge density  p = P which is so called polarization or the density of dipole moments.homogeneous polarization

16 15. 7. 200316 Inserting a Dielectric Into a Capacitor IV Inserting dielectrics is actually the most effective way to increase the capacitance. Since the electric field decreases, the absolute “breakdown” charge increases. Moreover for most dielectrics their breakdown intensity (or dielectric strength) is higher than that of air. They are better insulators!

17 15. 7. 200317 Energy Density in Dielectrics If we define the permitivity of a material as:  = K  0 =  r  0 and use it in all formulas where  0 appears. For instance the energy density can be written as  E 2 /2. If dielectrics are non-linear or/and non- uniform their description is considerably more complicated!

18 15. 7. 200318 Capacitor Partly Filled with a Dielectrics If we neglect the effects near the edges of the dielectrics, we can treat the system as a serial or/and parallel combination of capacitors, depending on the particular situation.

19 15. 7. 200319 Concluding Remarks To Electrostatics We have illustrated most of things on very simplified examples. Now we know relatively deeply all the important qualitative principles of the whole electrostatics. This should help us to understand easier the following parts ad well as functioning of any device based on electrostatics!

20 15. 7. 200320 Homework The homework from yesterday is due tomorrow!

21 15. 7. 200321 Things to Read This lecture covers : Chapter 24 – 4, 5, 6 Advance reading : Chapter 25 – 1, 2, 3, 5, 6

22 Charging a Capacitor Let at some point of charging the capacitor C have some voltage V(q) which depends on the current charge q. To move a charge dq across V(q) we do work dE p = V(q)dq. So the total work to reach the charge Q is: ^

23 Polarization  Dipole Moment Density I Let us take some volume V which is small in the macroscopic scale but large in the microscopic scale so it is representative of the whole sample:

24 Polarization  Induced Surface Charge Density II Let a single dipole moment p = lq be confined in a prism of the volume v = al. A volume V of the uniformly polarized dielectric is built of the same prisms, so the polarization must be the same as in any of them:

25 Polarization III The result field in the dielectric : We can express the original charge density: So the original field is distributed to the result field and the polarization according to the ability of the dielectric to be polarized.

26 Polarization IV In linear dielectrics is proportional to the result field. They are related by the dielectric susceptibility  : ^ The result field E is K times weaker than the original field E 0 and can also define the permitivity of a dielectric material as .


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