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The capacitors in the Figure (Figure 1) are initially uncharged and are connected, as in the diagram, with switch S open. The applied potential difference is Vab = + 210 V. Figure 1 of 1 Part A What is the potential difference Vcd ? Express your answer using two significant figures. Submit Request Answer Part B What is the potential difference Vad after switch S is closed? Submit Request Answer Part C What is the potential difference Vdb after switch S is closed? Vdb = V Submit Request Answer Part D What is the potential difference Vac after switch S is closed? Vac = V Part E What is the potential difference Vcb after switch S is closed? Submit Request Answer Part F How much charge flowed through the switch when it was closed?

The capacitors in the Figure (Figure 1) are initially uncharged and are connected, as in the diagram, with switch S open. The applied potential difference is Vab = + 210 V. Figure 1 of 1 Part A What is the potential difference Vcd ? Express your answer using two significant figures. Submit Request Answer Part B What is the potential difference Vad after switch S is closed? Submit Request Answer Part C What is the potential difference Vdb after switch S is closed? Vdb = V Submit Request Answer Part D What is the potential difference Vac after switch S is closed? Vac = V Part E What is the potential difference Vcb after switch S is closed? Submit Request Answer Part F How much charge flowed through the switch when it was closed?The capacitors in the Figure (Figure 1) are initially uncharged and are connected, as in the diagram, with switch S open. The applied potential difference is Vab = + 210 V. Figure 1 of 1 Part A What is the potential difference Vcd ? Express your answer using two significant figures. Submit Request Answer Part B What is the potential difference Vad after switch S is closed? Submit Request Answer Part C What is the potential difference Vdb after switch S is closed? Vdb = V Submit Request Answer Part D What is the potential difference Vac after switch S is closed? Vac = V Part E What is the potential difference Vcb after switch S is closed? Submit Request Answer Part F How much charge flowed through the switch when it was closed?The capacitors in the Figure (Figure 1) are initially uncharged and are connected, as in the diagram, with switch S open. The applied potential difference is Vab = + 210 V. Figure 1 of 1 Part A What is the potential difference Vcd ? Express your answer using two significant figures. Submit Request Answer Part B What is the potential difference Vad after switch S is closed? Submit Request Answer Part C What is the potential difference Vdb after switch S is closed? Vdb = V Submit Request Answer Part D What is the potential difference Vac after switch S is closed? Vac = V Part E What is the potential difference Vcb after switch S is closed? Submit Request Answer Part F How much charge flowed through the switch when it was closed?

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Part A The capacitors in the Figure (Figure 1) are initially uncharged and are connected, as in the diagram, with switch S open. The applied potential difference is V a b = + 210 V .
Figure 1 of 1 What is the potential difference V c d ? Express your answer using two significant figures. Submit Request Answer Part B
What is the potential difference V a d after switch S is closed? Submit Request Answer
Part C
What is the potential difference V d b after switch S is closed?
V d b =
V Submit Request Answer Part D
What is the potential difference V a c after switch S is closed?
V a c = V
Part E
What is the potential difference V c b after switch S is closed? Submit Request Answer Part F
How much charge flowed through the switch when it was closed?

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