For the circuit shown in the figure below, the capacitors were each discharged before being connected to the voltage source V = 214 V. 4.0 µF V 12.0 μF 15.0 μ . (a) Find the equivalent capacitance of the combination. (b) Find the charge stored on the positively charged plate of each capacitor. 15.0 µF capacitor 4.0 µF capacitor | HC 12.0 µF capacitor | µC

A

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**Capacitor Circuit Analysis** For the circuit shown, the capacitors were each discharged before being connected to the voltage source \( V = 214 \, \text{V} \). **Diagram:** - The circuit features three capacitors in parallel: \(15.0 \, \mu \text{F}\), \(4.0 \, \mu \text{F}\), and \(12.0 \, \mu \text{F}\). - These capacitors are connected to a voltage source (\( V \)) of 214 volts. **Tasks:** **(a) Find the equivalent capacitance of the combination.** - Equivalent Capacitance: [Text Box] \( \mu \text{F} \) **(b) Find the charge stored on the positively charged plate of each capacitor.** - \(15.0 \, \mu \text{F}\) capacitor: [Text Box] \(\mu \text{C}\) - \(4.0 \, \mu \text{F}\) capacitor: [Text Box] \(\mu \text{C}\) - \(12.0 \, \mu \text{F}\) capacitor: [Text Box] \(\mu \text{C}\) **(c) Find the voltage across each capacitor.** - \(15.0 \, \mu \text{F}\) capacitor: [Text Box] \( \text{V} \) - \(4.0 \, \mu \text{F}\) capacitor: [Text Box] \( \text{V} \) - \(12.0 \, \mu \text{F}\) capacitor: [Text Box] \( \text{V} \) **(d) Find the energy stored in each capacitor.** - \(15.0 \, \mu \text{F}\) capacitor: [Text Box] \( \text{mJ} \) - \(4.0 \, \mu \text{F}\) capacitor: [Text Box] \( \text{mJ} \) - \(12.0 \, \mu \text{F}\) capacitor: [Text Box] \( \text{mJ} \) This exercise involves calculating capacitance, charge, voltage, and energy stored in capacitors when connected to a voltage source, which helps in understanding the behavior of capacitors in electrical circuits