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summary C o A/ d 2 o L / ln( b / a ) C 4 o • Capacitance • Parallel plates, coaxial cables, Earth • Series and parallel combinations • Energy in a capacitor • Dielectrics • Dielectric strength ab 4 o a ba b a Q CV 1 1 1 .. C C1 C2 C C C C1 C2 ... 2 1 Q U CV 2 2 2C More complex capacitor systems In general a capacitor system may consist of smaller capacitor groups that can be identified as connected "in parallel" or "in series" In the example of the figure C1 and C2 in fig.a are connected in parallel. They can be substituted by the equivalent capacitor C12 C1 C2 as shown in fig.b. Capacitors C12 and C3 in fig.b are connected in series. They can be substituted by a single capacitor C123 as shown in fig.c C123 is given by the equation: (25 - 12) 1 1 1 C123 C12 C3 • Series combinations reduce the capacitance. Equal C reduce by the number involved. • In parallel the capacitance increases. A basket of 4 capacitors, each of C = 6 nF. How can you arrange them to get a) 1.5 nF b) 2 nF g) 2.4 nF c) 3 nF h) 3.6 nF d) 4 nF i) 4.5 nF j) 6 nF e) 12 nF k) 18 nF f) 24 nF clicker All C’s are 8.00 nF. The battery is 12 V. What is the equivalent capacitance? a. b. c. d. e. 4 nF 6 nF 8 nF 10 nF 12 nF All C’s are 8.00 nF. The battery is 12 V. What is the equivalent capacitance? C12 = 4 nF C123 = 12 nF Q123 = C123 x V = 144 nC Q3 = C3 x V = 96 nC Q12 = C12 x V = 48 nC U123 = ½ C123V2 = ½ x 12x10-9 x122 = 864 nJ U1 = ½ C1V12 = ½ x 8x10-9 x62 = 144 nJ = U2 U3 = ½ x 8x10-9 x122 = 576 nF C3 stores most energy, also the highest electric field and most charge, the most stressed part of the circuit. Circuits • All capacitors being the same, rank the equivalent capacitances of the four circuits. C1 = C3 = 8.00 μF, C2 = C4 = 6.00 μF, V = 12V When the switch S is closed, how much charge flows through point P C123 2.4 µF, q = 28.8 µC C2 C24 = 12 µF C1234 = 3 µF q =36 µC Δq = 7.2 µC C o A/ d C Cair Capacitor with a dielectric q -q In 1837 Michael Faraday investigated what happens to the V capacitance C of a capacitor when the gap between the plates is completely filled with an insulator (a.k.a. dielectric) Faraday discovered that the new capacitance is given by : q' V -q' C Cair Here Cair is the capacitance before the insertion of the dielectric between the plates. The factor is known as the dielectric constant of the material. Faraday's experiment can be carried out in two ways: q V In this case a battery remains connected to the plates . -q q -q 1. With the voltage V across the plates remaining constant This is shown in fig.a V' 2. With the charge q of the plates remaining constant. In this case the plates are isolated from the battery This is shown in fig.b (25 - 15) C Cair q -q V This is bacause the battery remains connected to the plates After the dielectric is inserted between the capacitor plates the plate charge changes from q to q q q' V -q' q Fig.a : Capacitor voltage V remains constant V q κq q The new capacitance C κ κCair V V V Fig.b : Capacitor charge q remains constant This is bacause the plates are isolated -q After the dielectric is inserted between the capacitor plates q -q V' the plate voltage changes from V to V The new capacitance C V q q q Cair V V / V (25 - 16) C o A 1 2 2d If the areas are A1 and A-A1. C Effect of a dielectric : C κC o d A 2 A1 (1 2 C123 2.4 µF, q = 28.8 µC C2 C24 = 12 µF C1234 = 3 µF q =36 µC The force on a filling dielectric as it is inserted between the parallel plates of a capacitor. C C1 C2 1 dC C dx L o d x A1 1 With the battery connected, U1 = ½CV2 F x 1 dU1 U1 dx L L L With the battery disconnected, U2 = Q2/2C F 1 dU 2 U2 dx L With the battery connected, since x is increasing downwards, a negative force is upwards, pushing the dielectric away. With the battery disconnected, the force is positive and pointed downwards, pulling in the dielectric. The force is proportional to (κ-1) and inversely to L. A question What is the equivalent capacitance between the points A and B? A. B. C. D. E. 1 μF 2 μF 4 μF 10μF None of these A What would a 10V battery do, i.e. how much charge will it provide, when it is connected across A and B? 40 μC B Question • A parallel-plate capacitor has a plate area of 0.3m2 and a plate separation of 0.1mm. If the charge on each plate has a magnitude of 5x10-6 C then the force exerted by one plate on the other has a magnitude of about: A. 0 B. 5N C. 0. 9N D. 1 x104 N E. 9 x 105 N F qE q2 2 o A 5 10 6 2 2 8.85 10 12 0.3 4.71N The electric field = σ/2εo why? Question • A parallel-plate capacitor has a plate area of 0.3m2 and a plate separation of 0.1mm. If the charge on each plate has a magnitude of 5x106 C then the force exerted by one plate on the other has a magnitude of about: • A. 0 B. 5N C. 9N D. 1 x104 N E. 9 x 105 N A question • Each of the four capacitors shown is 500 μF. The voltmeter reads 1000V. The magnitude of the charge, in coulombs, on each capacitor plate is: A. 0.2 these B. 0.5 C. 20 D. 50 E. none of HITT A parallel-plate capacitor has a plate area of 0.2m2 and a plate separation of 0.1 mm. To obtain an electric field of 2.0 x 106 V/m between the plates, the magnitude of the charge on each plate should be: A. 8.9 x 10-7 C B. 1.8 x 10-6 C C. 3.5 x 10-6 C D. 7.1 x 10-6 C E. 1.4 x 10-5 C