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Ch 17: Electrical Energy and Current 17 -2: Capacitance

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1 Ch 17: Electrical Energy and Current 17 -2: Capacitance

2 A capacitor is a device whose purpose is to store electrical energy which can then be released in a controlled manner during a short period of time. A capacitor consists of 2 spatially separated conductors which can be charged to +Q and -Q respectively.

3 Q = magnitude of charge on the plates V = potential difference
The capacitance is defined as the ratio of the charge on one conductor of the capacitor to the potential difference between the conductors. C = capacitance Q = magnitude of charge on the plates V = potential difference The capacitance belongs only to the capacitor, independent of the charge and voltage. [The unit of capacitance is the Farad: 1 F = 1C/V]

4 ° = permittivity of free space = constant ° = 8.85 x 10-12 C2/N•m2
Capacitance is a measure of the conductor’s ability to store charge, it depends on the geometry of the capacitor. C = ° A d ° = permittivity of free space = constant ° = 8.85 x C2/N•m2 Capacitance for a parallel plate capacitor in a vacuum

5 Parallel Plate Capacitor
The device consists of plates of positive and negative charge The total electric field between the plates is given by The field outside the plates is zero

6 Capacitor with a Dielectric
A dielectric is an insulating material inserted between the plates to increase capacitance. New capacitance given by: C = K Co K = dielectric constant Co = capacitance in a vacuum

7

8 Sample Problem An empty parallel plate capacitor, Co = 25 mF is charged with a 12 V battery. The battery is disconnected and the region between the plates is filled with water. Find the capacitance, charge and voltage of the water-filled capacitor. Given: Co = 25 mF Vo = 12 V

9 Co = ° A = 25 mF d the geometry of the plates doesn’t change so, C = KCo = 80 (25 x 10-6 F) = 2.0 x 10-3 F

10 Since the battery is disconnected, the charge on the plates stays the same
Q = CoVo = (25 x 10-6 F)(12V) = 3.0 x 10-4 C

11 The new voltage is given by: q = CV  V= q/C =. 3. 0 x 10– 4 C. 2
The new voltage is given by: q = CV  V= q/C = 3.0 x 10– 4 C 2.0 x 10-3 F = 0.15 V

12 Energy stored in a capacitor
The energy stored in the field can be found by: PE = ½ qV Since q = CV PE = ½ CV2 equivalently PE = q2 2C Note: E here stands for energy, measured in Joules, Not electric field!

13 Lightning (the atmosphere is a BIG capacitor!!)
_ + Collisions produce charged particles. The heavier particles (-) sit near the bottom of the cloud; the lighter particles (+) near the top. Stepped Leader Negatively charged electrons begin zigzagging downward. Attraction As the stepped leader nears the ground, it draws a streamer of positive charge upward. Flowing Charge As the leader and the streamer come together, powerful electric current begins flowing Contact! Intense wave of positive charge, a “return stroke,” travels upward at 108 m/s

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