Figure R www 10.0 pF 20.0 pF 40.0 pF < 30.0 pF 1 of 1 > ▼ ▼ ▼ Part G After the switch is closed, find the maximum potential difference across the 30.0 pF capacitor. Express your answer in volts. [VD] ΑΣΦ V30 = Submit Part H V40 = Submit Part I After the switch is closed, find the maximum potential difference across the 40.0 pF capacitor. Express your answer in volts. IVE| ΑΣΦ 1 IA = Submit Part J 5 Request Answer Submit Request Answer After the switch is closed, find the maximum reading of the ammeter A. Express your answer in amperes. —| ΑΣΦ | 6 Request Answer ? Request Answer ? After the switch is closed, find the time constant for the circuit. Express your answer in picoseconds. IVE] ΑΣΦ 3 www. ? ? V V A ps

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## Transcription of Educational Exercise on Capacitors and Circuits ### Problem Statement You are given a circuit diagram and a series of questions to solve based on the circuit components. The circuit includes capacitors, a resistor, an ammeter, and a switch. Your task is to find various electrical properties after the switch is closed. ### Circuit Description (Figure) The circuit consists of: - A switch (initially open). - A resistor \( R \) in series with the switch. - Four capacitors with the following capacitances: 10.0 pF, 20.0 pF, 30.0 pF, and 40.0 pF connected as shown. - An ammeter \( A \) to measure current. - An AC voltage source (not explicitly labeled with a value). ### Exercise Parts **Part G:** - **Objective:** Find the maximum potential difference across the 30.0 pF capacitor. - **Unit of Answer:** Volts - **Input Field:** \( V_{30} = \) **Part H:** - **Objective:** Find the maximum potential difference across the 40.0 pF capacitor. - **Unit of Answer:** Volts - **Input Field:** \( V_{40} = \) **Part I:** - **Objective:** Find the maximum reading of the ammeter \( A \). - **Unit of Answer:** Amperes - **Input Field:** \( I_A = \) **Part J:** - **Objective:** Find the time constant of the circuit. - **Unit of Answer:** Picoseconds - **Input Field:** \( \tau = \) ### Input Interaction Each part of the exercise provides a space for the user to input their answer. A "Submit" button is available to submit the response, followed by an option to request a hint or further assistance. This transcription is designed for an educational setting, helping students engage with electronic circuit analysis through interactive problem-solving.

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In the circuit shown in (Figure 1), the capacitors are all initially uncharged, and the battery has no appreciable internal resistance. Assume that \( \mathcal{E} = 51.0 \, \text{V} \) and \( R = 23.0 \, \Omega \). *Note: Figure 1 is not displayed. For detailed analysis, refer to the accompanying circuit diagram in the study materials.*