All MCAT Physical Resources
Example Questions
Example Question #611 : Mcat Physical Sciences
Batteries and AC current are often used to charge a capacitor. A common example of capacitor use is in computer hard drives, where capacitors are charged in a specific pattern to code information. A simplified circuit with capacitors can be seen below. The capacitance of C1 is 0.5 μF and the capacitances of C2 and C3 are 1 μF each. A 10 V battery with an internal resistance of 1 Ω supplies the circuit.
Capacitors in series share the same __________, while capacitors in parallel share the same __________.
Current . . . charge
Voltage . . . current
Current . . . voltage
Charge . . . current
Current . . . voltage
As with resistors, capacitors in series share the same current. This is a re-statement of the law of conservation of charge. In contrast, capacitors and resistors in parallel share the same voltage.
Example Question #51 : Circuits
Batteries and AC current are often used to charge a capacitor. A common example of capacitor use is in computer hard drives, where capacitors are charged in a specific pattern to code information. A simplified circuit with capacitors can be seen below. The capacitance of C1 is 0.5 μF and the capacitances of C2 and C3 are 1 μF each. A 10 V battery with an internal resistance of 1 Ω supplies the circuit.
How much total charge is stored by the capacitors of the circuit?
25μC
20μC
10μC
15μC
10μC
We are asked how much charge is stored in total on the circuit. We can use the equivalent capacitance and the voltage supplied by the battery to calculate the charge. Remember that Q = CV, where Q is the total charge, C is the equivalent capacitance, and V is the voltage. We must first solve for equivalent capacitance.
C2 and C3 are capacitors in series, while C1 is in parallel.
C23 = 0.5μF
Ceq = C23 + C1 = 0.5μF + 0.5μF = 1μF
Now we can plug in the Ceq and battery voltage to find the charge.
Q = (1μF)(10V) = 10μC
Example Question #611 : Mcat Physical Sciences
Batteries and AC current are often used to charge a capacitor. A common example of capacitor use is in computer hard drives, where capacitors are charged in a specific pattern to code information. A simplified circuit with capacitors can be seen below. The capacitance of C1 is 0.5 μF and the capacitances of C2 and C3 are 1 μF each. A 10 V battery with an internal resistance of 1 Ω supplies the circuit.
While the capacitor is charging, does the capacitor generate a magnetic field?
Yes
Cannot be determined
No
Yes
This question asks us to consider electromagnetism and what happens when a capacitor is charging. When a capacitor is charging, charge is accumulating on the surface over a period of time. Given that the electric field due to a capacitor is given by the formula E = σ/ε0, where σ is the charge per unit area and ε0 is the constant of permeability of free space, we can see that E is directly proportional to σ; therefore, the more charge that builds up, the higher the resulting E field.
Because σ is changing during charging, and thus E is changing, we also know that a magnetic field, B, must be created.
Remember the principle—a changing electric field induces a changing magnetic field, and a changing magnetic field induces a changing electric field.
Example Question #12 : Capacitors And Dielectrics
Batteries and AC current are often used to charge a capacitor. A common example of capacitor use is in computer hard drives, where capacitors are charged in a specific pattern to code information. A simplified circuit with capacitors can be seen below. The capacitance of C1 is and the capacitances of C2 and C3 are each. A battery with an internal resistance of supplies the circuit.
How much potential energy is stored by the capacitors of the circuit?
First, we need to determine the type of energy being stored by the capacitors in the circuit. As this is an electric circuit, electric energy is being stored. Thus, we can use the formula for potential energy stored in a capacitor, U = ½CV2. We must first find the equivalent capacitance.
C2 and C3 are capacitors in series, while C1 is in parallel.
C23 = 0.5μF
Ceq = C23 + C1 = 0.5μF + 0.5μF = 1μF
U = ½CV2 = ½(1μF)(10V)2 = 5 * 10-5J
Example Question #12 : Capacitors And Dielectrics
Which of the following arrangements of parallel conducting plates would store the most charge when connected in series with a battery of voltage ?
Assume that in each arrangement, each plate has area .
Plate separation of ; air fills the space between them
Plate separation of ; air fills the space between them
Plate separation of ; glass fills the space between them
Plate separation of ; air fills the space between them
Plates separated of ; glass fills the space between them
Plate separation of ; glass fills the space between them
Relevant equations:
The first equation shows that charge is directly proportional to capacitance , so we want to maximize in order to find the maximum charge.
The second equation shows that is directly proportional to the dielectric constant , and inversely proportional to distance . To increase capacitance, we need to be large and to be small.
A smaller distance and a larger dielectric constant (choosing glass instead of air) will lead to a large stored charge.
Example Question #56 : Circuits
An RC circuit is assembled by connecting a voltage source, a resistor, and a capacitor in series. The capacitor in the circuit has a potential difference of . After discharging the capacitor for two seconds, the potential difference of the capacitor drops to . What are the approximate capacitance and time constant of this circuit if the resistor has a resistance of ?
To solve this question, we need to use the equation that describes voltage decay during capacitor discharging:
Here, is the voltage after a certain amount of time, is the initial voltage, is the time elapsed, is the resistance of the resistor, and is the capacitance of the capacitor. We can rearrange this equation in such a way that we solve for capacitance, :
To remove the exponential from the equation, we need to take the natural logarithm of both sides:
Solving for gives us:
The time constant, , of an RC circuit is the product of the resistance and the capacitance; therefore, the time constant of this circuit is:
Example Question #91 : Electricity And Magnetism
During discharge, the decay of voltage in a capacitor is an example of __________ decay, the decay of current in a capacitor is an example of __________ decay, and the decay of charge in a capacitor is an example of __________ decay.
linear . . . exponential . . . exponential
exponential . . . exponential . . . exponential
linear . . . linear . . . linear
exponential . . . linear . . . linear
exponential . . . exponential . . . exponential
A capacitor is an electrical device consisting of two parallel conducting plates that store charge. A capacitor undergoes two processes: charging and discharging. During charging, a capacitor accumulates and stores charge between the two plates. During discharge, a capacitor loses the stored charge. Since there is a decrease in the amount of charge during discharge, there is also a decrease (or decay) in current and voltage in a discharging capacitor. The decay of all these parameters is characterized by the equation:
Here, and denote the variable (voltage, current, or charge), denotes the time elapsed, denotes the resistance of the resistor, and denotes the capacitance of the capacitor. This is an equation for exponential decay; therefore, all the variables undergo exponential decay in a discharging capacitor.
Example Question #58 : Circuits
A capacitor has a capacitance of and is connected in series with a resistor to form an RC circuit. At , the capacitor has a potential difference of . At , the potential difference has dropped to .
What is the resistance of the resistor?
The question states that the potential difference dropped from to in . The percentage of voltage drop is:
This means that there was a voltage drop in . The definition of time constant is the time it takes for a capacitor to discharge to of its original value, or have a drop; therefore, the time constant for this circuit is .
The time constant, tau, for an RC circuit is the product of the resistance of the resistor and the capacitance of the capacitor:
We can use this equation to solve for the resistance of the resistor:
Solving for resistance gives us:
Notice that you could have used the voltage decay equation to solve this problem; however, knowing the definition of time constant simplifies the problem and reduces the amount of calculations.
Example Question #1 : Resistivity
Which of the following factors would decrease the resistance through an electrical cord?
Decreasing the cross-sectional area of the cord
Increasing the length of the cord
Increasing the cross-sectional area of the cord
Increasing the resistivity
Increasing the cross-sectional area of the cord
The equation for resistance is given by .
From this equation, we can see the best way to decrease resistance is by increasing the cross-sectional area, , of the cord. Increasing the length, , of the cord or the resistivity, , will increase the resistance.
Example Question #2 : Resistivity
An electrician wishes to cut a copper wire that has no more than of resistance. The wire has a radius of 0.725mm. Approximately what length of wire has a resistance equal to the maximum ?
2.6cm
960m
38m
9.6m
10cm
960m
To relate resistance R, resistivity , area A, and length L we use the equation.
Rearranging to isolate the quantity we wish to solve for, L, gives the equation . We must first solve for A using the radius, 0.725mm.
Plugging in our numbers gives the answer, 960m.
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