A large resistance is needed to make sure the voltmeter has the same current through it as the circuit component, so the potential difference across the voltmeter is the same as that across the component.

A large resistance is needed to make sure a large current passes through the voltmeter, so the rest of the circuit is not affected.

A large resistance is needed to make sure negligible current passes through the voltmeter, so the rest of the circuit is not affected

A large resistance is needed to make sure the current through the voltmeter has the same nonnegligible value whenever it is used, regardless of the current in the rest of the circuit.

No, because a change in potential difference does not affect the properties of the wire.

No, because if the wire heats up enough, its resistivity may change significantly.

Yes, because the wire dimensions have not changed.

Yes, because according to Ohm’s law, the resistance is a constant of proportionality between V and I

The brightness of the lightbulb is proportional to the square of the current

The brightness of the lightbulb is not proportional to the square of the potential difference

The resistance of the lightbulb for each data point can be determined by dividing the potential difference by the current.

The resistance of the lightbulb is not constant.

Yes. There is a loop that contains just R and the 10 ohm resistor. The potential difference across R plus that across the 10 ohm resistor will equal the power supply emf. Therefore, the potential difference across resistor R is 36V - 4V = 32V.

No. The 10 ohm and 6 ohm resistors are in parallel, so they have the same potential difference. There is a loop that contains R and both the 10 ohm and 6 ohm resistors. So the potential difference across the 10 ohm resistor plus that across the 6 ohm resistor plus that across resistor R will equal the power supply emf. Therefore, the potential difference across resistor R is 36V - 4V - 4V = 28V.

No. The 10ohm, 6 ohm, and 4 ohm resistors are in parallel, so they have the same potential difference. They are in series with resistor R, so the potential difference across each of the three parallel resistors plus that of resistor R will equal the power supply emf. Therefore, the potential difference across resistor R is 36V - 4V - 4V - 4V = 24V.

No. All four resistors are in parallel, so they will all have the same potential difference. So the potential difference across is equal to 4V.