Pre-Class 7

A  The voltage across both the resistor and the capacitor is equal to the terminal voltage of the battery.

B  The voltage across the resistor is zero, and the voltage across the capacitor is equal to the terminal voltage of the battery.

C  The voltage across the resistor is equal to the terminal voltage of the battery, and the voltage across the capacitor is zero.

D  The voltage across both the resistor and the capacitor is zero.

E  The voltage across both the resistor and the capacitor is equal to one-half of the terminal voltage of the battery.

A  The voltage across both the resistor and the capacitor is equal to one-half of the terminal voltage of the battery.

B  The voltage across the resistor is zero, and the voltage across the capacitor is equal to the terminal voltage of the battery.

C  The voltage across the resistor is equal to the terminal voltage of the battery, and the voltage across the capacitor is zero.

D  The voltage across both the resistor and the capacitor is equal to the terminal voltage of the battery.

E  The voltage across both the resistor and the capacitor is zero.

A  The charge stored on each of the capacitors is the same. The equivalent capacitance of the combination is less than the capacitance of either of the capacitors. The algebraic sum of the voltages across the two capacitors is equal to the voltage supplied by the battery.

B  The sum of the charge stored on each capacitor is equal to the charge supplied by the battery. The equivalent capacitance of the combination is greater than the capacitance of either of the capacitors. The voltage across each of the capacitors is the same.

C  The voltage across each of the capacitors is the same. The equivalent capacitance of the combination is less than the capacitance of either of the capacitors. The algebraic sum of the voltages across the two capacitors is equal to the voltage supplied by the battery.

D  The charge stored on each of the capacitors is the same. The equivalent capacitance of the combination is less than the capacitance of either of the capacitors. The sum of the charge stored on each capacitor is equal to the charge supplied by the battery.

A  The sum of the charges stored on each capacitor is equal to the charge supplied by the battery. The voltage across each of the capacitors is the same. The equivalent capacitance of the combination of the two capacitors is greater than the capacitance of either of the capacitors.

B  The charge stored on each of the capacitors is the same. The voltage across each of the capacitors is the same. The equivalent capacitance of the combination of the two capacitors is greater than the capacitance of either of the capacitors.

C  The sum of the charges stored on each capacitor is equal to the charge supplied by the battery. The voltage across each of the capacitors is the same.The algebraic sum of the voltages across the two capacitors is equal to the voltage supplied by the battery.

D  The equivalent capacitance of the combination of the two capacitors is less than the capacitance of either of the capacitors. The charge stored on each of the capacitors is the same. The algebraic sum of the voltages across the two capacitors is equal to the voltage supplied by the battery.

A  The energy stored in the capacitor is decreased to one-fourth of its original value.

B  The energy stored in the capacitor doubles its original value.

C  The energy stored in the capacitor remains constant.

D  The energy stored in the capacitor is decreased to one-half of its original value.

E  The energy stored in the capacitor quadruples its original value.

A  The energy stored in the capacitor doubles its original value.

B  The energy stored in the capacitor is decreased to one-fourth of its original value.

C  The energy stored in the capacitor is decreased to one-half of its original value.

D  The energy stored in the capacitor remains constant.

E  The energy stored in the capacitor quadruples its original value.