Consider the circuit shown in the figure below. Calculate the voltage across the capacitor C6 assuming the following potential source and capacitor values: Vo = 12.0 V C₁ = 4.0 μF, C2 = 4.0 μF, C3 = 3.0 μF C4 2.26 μF, C5 = 4.42 μF, C6 = 10.0 μF C C₂ I Image size: S M L Max

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**Equivalent Capacitance / Mixed** Consider the circuit shown in the figure below. Calculate the voltage across the capacitor \( C_6 \) assuming the following potential source and capacitor values: - \( V_0 = 12.0 \, V \) - \( C_1 = 4.0 \, \mu F \) - \( C_2 = 4.0 \, \mu F \) - \( C_3 = 3.0 \, \mu F \) - \( C_4 = 2.26 \, \mu F \) - \( C_5 = 4.42 \, \mu F \) - \( C_6 = 10.0 \, \mu F \) **Diagram Explanation:** The circuit diagram consists of a combination of capacitors arranged in a mixed series and parallel configuration. Below is a detailed description of each section: 1. **Series Components:** - Two capacitors, \( C_1 \) and \( C_2 \), are connected in series. This series combination is then connected in parallel with \( C_3 \). 2. **Parallel Components:** - Capacitors \( C_4 \), \( C_5 \), and \( C_6 \) are also in parallel to each other, forming a block that is connected in series with the initial parallel combination. To solve for the voltage across \( C_6 \), use the principles of series and parallel capacitor calculations to find the equivalent capacitance and distribution of voltage. Please enter a numerical answer below. Accepted formats are numbers or "e" based scientific notation e.g. 0.23, -2, 1e6, 5.23e-8 **Enter answer here:** \(\_\_\_\) Volts