260 likes | 470 Views
1. 2. 3. 4. 5. Determine the charge stored by {image} when {image} , {image} , {image} , and {image} . {applet}. {image} {image} {image} {image} {image}. 1. 2. 3. 4. 5. Determine the energy stored in the {image} capacitor. {applet}. {image} {image} {image} {image} {image}. 1.
E N D
1. 2. 3. 4. 5. Determine the charge stored by {image} when {image} , {image} , {image} , and {image} . {applet} • {image} • {image} • {image} • {image} • {image}
1. 2. 3. 4. 5. Determine the energy stored in the {image} capacitor. {applet} • {image} • {image} • {image} • {image} • {image}
1. 2. 3. 4. 5. Determine the equivalent capacitance of the circuit shown below. {applet} • {image} • {image} • {image} • {image} • {image}
1. 2. 3. 4. 5. Determine the energy stored in {image} when {image} , {image} , {image} , and {image} . {applet} • {image} • {image} • {image} • {image} • {image}
1. 2. 3. 4. 5. Determine the equivalent capacitance of the combination shown when {image} ? {applet} • {image} • {image} • {image} • {image} • {image}
1. 2. 3. 4. 5. A parallel plate capacitor of capacitance {image} has plates of area {image} with separation {image} between them. When it is connected to a battery of voltage {image} , it has charge of magnitude {image} on its plates. It is then disconnected from the battery and the space between the plates is filled with a material of dielectric constant 4. After the dielectric is added, what are the magnitudes of the charge on the plates and the potential difference between them? • {image} , {image} • {image} , {image} • {image} , {image} • {image} , {image} • {image} , {image}
1. 2. 3. 4. 5. Determine the equivalent capacitance of the combination shown when {image} . {applet} • {image} • {image} • {image} • {image} • {image}
1. 2. 3. 4. 5. A parallel plate capacitor of capacitance {image} has plates of area {image} with separation {image} between them. When it is connected to a battery of voltage {image} , it has charge of magnitude {image} on its plates. While it is connected to the battery the space between the plates is filled with a material of dielectric constant 6. After the dielectric is added, what is the magnitude of the charge on the plates and the potential difference between them? • {image} , {image} • {image} , {image} • {image} , {image} • {image} , {image} • {image} , {image}
1. 2. 3. 4. 5. A parallel plate capacitor of capacitance {image} has plates of area {image} with separation {image} between them. When it is connected to a battery of voltage {image} , it has charge of magnitude {image} on its plates. The plates are pulled apart to a separation {image} while the capacitor remains connected to the battery. After the plates are {image} apart, what is the magnitude of the charge on the plates and the potential difference between them? • {image} , {image} • {image} , {image} • {image} , {image} • {image} , {image} • {image} , {image}
An initially uncharged parallel plate capacitor of capacitance {image} is charged to potential {image} by a battery. The battery is then disconnected. Which statement is right? • The magnitude of the electric field outside the space between the plates is approximately zero. • There is no charge on either plate of the capacitor. • The capacitor can be discharged by grounding any one of its two plates. • Charge is distributed evenly over both the inner and outer surfaces of the plates. • The capacitance increases when the distance between the plates increases.
1. 2. 3. 4. 5. A parallel plate capacitor of capacitance {image} has plates of area {image} with separation {image} between them. When it is connected to a battery of voltage {image} , it has charge of magnitude {image} on its plates. It is then disconnected from the battery and the plates are pulled apart to a separation {image} without discharging them. After the plates are {image} apart, what is the new capacitance and the potential difference between the plates? • {image} , {image} • {image} , {image} • {image} , {image} • {image} , {image} • {image} , {image}
1. 2. 3. 4. 5. A {image} capacitor is charged to an unknown potential {image} and then connected across an initially uncharged {image} capacitor. If the final potential difference across the {image} capacitor is {image} , determine {image} . • {image} • {image} • {image} • {image} • {image}
1. 2. 3. 4. 5. A {image} capacitor is charged to {image} and then connected across an initially uncharged {image} capacitor. What is the final potential difference across the {image} capacitor? • {image} • {image} • {image} • {image} • {image}
1. 2. 3. 4. 5. A {image} capacitor and a {image} capacitor are connected in parallel, and charged to a potential difference of {image} . How much energy is then stored in this capacitor combination? • {image} • {image} • {image} • {image} • {image}
1. 2. 3. 4. 5. A {image} capacitor initially charged to {image} and a {image} capacitor charged to {image} are connected to each other with the positive plate of each connected to the negative plate of the other. What is the final charge on the {image} capacitor? • {image} • {image} • {image} • {image} • {image}
1. 2. 3. 4. 5. A capacitor of unknown capacitance {image} is charged to {image} and then connected across an initially uncharged {image} capacitor. If the final potential difference across the {image} capacitor is {image} , determine {image} . • {image} • {image} • {image} • {image} • {image}
1. 2. 3. 4. 5. A {image} capacitor charged to {image} and a {image} capacitor charged to {image} are connected to each other, with the two positive plates connected and the two negative plates connected. What is the total energy stored in the {image} capacitor at equilibrium? • {image} • {image} • {image} • {image} • {image}
1. 2. 3. 4. 5. If {image} , how much energy is stored in the {image} capacitor? {applet} • {image} • {image} • {image} • {image} • {image}
1. 2. 3. 4. 5. Determine the equivalent capacitance of the circuit shown below. {applet} • {image} • {image} • {image} • {image} • {image}
1. 2. 3. 4. 5. A {image} capacitor and a {image} capacitor are connected in series, and charged to a potential difference of {image} . What is the resulting charge on the {image} capacitor? • {image} • {image} • {image} • {image} • {image}
1. 2. 3. 4. 5. What total energy is stored in the group of capacitors shown if the potential difference {image} is equal to {image} ? {applet} • {image} • {image} • {image} • {image} • {image}
1. 2. 3. 4. 5. What is the total energy stored in the group of capacitors shown if the charge on the {image} capacitor is {image} ? {applet} • {image} • {image} • {image} • {image} • {image}
1. 2. 3. 4. 5. What is the equivalent capacitance of the combination shown? {applet} • {image} • {image} • {image} • {image} • {image}
A capacitor stores charge {image} at a potential difference {image} If the voltage applied by a battery to the capacitor is doubled to {image} _____. • the capacitance falls to half its initial value and the charge remains the same • the capacitance and the charge both fall to half their initial values • the capacitance and the charge both double • the capacitance remains the same and the charge doubles
Two capacitors are identical. They can be connected in series or in parallel. If you want the smallest equivalent capacitance for the combination, you will connect them _____. • in series • in parallel • do the combinations have the same capacitance
You have three capacitors and a battery. In which of the following combinations of the three capacitors will the maximum possible energy be stored when the combination is attached to the battery? • Series. • Parallel. • Both combinations will store the same amount of energy.