Capacitors: Examples and Applications

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Explore examples of parallel-plate capacitors with varying dimensions and configurations, calculating capacitance, maximum charge, and energy storage. Understand how capacitors behave in circuits and how to determine equivalent capacitance in complex setups.


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  1. Chapter 26 Examples 26.1 parallel-plate capacitor with air between the plates has an area A = 2.00 x 10 -4 m 2and a plate separation d = 1.00 mm. Find its capacitance?.

  2. 4. Find the equivalent capacitance between a and b for the combination of capacitors shown in Figure. All capacitances are in microfarads.

  3. We reduce the combination step by step as indicated in the figure. The 1.0- m F and 3.0- mF capacitors are in parallel and combine according to the expression C eq = C 1 + C 2 = 4.0 mF. The 2.0-mF and 6.0-mF capacitors also are in parallel and have an equivalent capacitance of 8.0 mF. Thus, the upper branch in Figure consists of two 4.0-mF capacitors in series, which combine as follows: The lower branch in Figure consists of two 8.0- F capacitors in series, which combine to yield an equivalent capacitance of 4.0 F. Finally, the 2.0- F and 4.0- F capacitors in Figure are in parallel and thus have an equivalent capacitance of 6.0 F.

  4. 6. A parallel-plate capacitor has plates of dimensions 2.0 cm by 3.0 cm separated by a 1.0-mm thickness of paper. (A) Find its capacitance.

  5. (B) What is the maximum charge that can be placed on the capacitor?

  6. 7. A parallel-plate capacitor is charged with a battery to a charge Q0, as shown in Figure a. The battery is then removed, and a slab of material that has a dielectric constant 1 is inserted between the plates, as shown in Figure b. Find the energy stored in the capacitor before and after the dielectric is inserted.

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