MCAT Physical : Voltage, Energy, and Power

Study concepts, example questions & explanations for MCAT Physical

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Example Questions

Example Question #11 : Circuits

During the cold winter months, some gloves have the ability to provide extra warmth due to an internal heating source. A simplified circuit, similar to those in electric gloves, is comprised of a 9 V battery with no internal resistance and three resistors as shown in the image below. 

Screen_shot_2013-10-09_at_11.08.15_pm

What is the voltage drop across the circuit?

Possible Answers:

9V

4.5V

0V

2.25V

Correct answer:

9V

Explanation:

This question asks us directly about one of Kirchhoff’s Loop Laws—more specifically the second law that states that the sum of the voltage around any loop must be equal to zero.

ΣVcircuit = 0V

Because the battery provides 9V, the voltage drop across the circuit must be 9V.

As an aside, the other Kirchhoff Law, the first law, states that current into a junction must equal the current that exits the junction, due to conservation of charge.

Example Question #11 : Voltage, Energy, And Power

During the cold winter months, some gloves have the ability to provide extra warmth due to an internal heating source. A simplified circuit, similar to those in electric gloves, is comprised of a 9V battery with no internal resistance and three resistors as shown in the image below. 

Screen_shot_2013-10-09_at_11.08.15_pm

What is the voltage drop across RA?

Possible Answers:

Correct answer:

Explanation:

First, we need to determine the voltage drop across R1, and then we can subtract that from the 9V battery to determine the voltage drop across RA. Given that RA and R4 are in parallel, we know that the voltage drop across each is the same.

The voltage drop across R1 can be calculated using the Icircuit (all the current generated by the battery’s potential difference must pass through R1 because it is in direct series with the battery), and the resistance of the resistor.

I can be calculated by V = IR because we have the voltage drop across the circuit (9V) and can calculate the equivalent resistance.

By taking the inverse of the equation, we can see that RA4 is equal to 2Ω.

Req = RA4 + R1 = 2Ω + 2Ω = 4Ω

Now, using V=IR allows us to find the current in the circuit.

V = IR

I = V/R = 9V/4Ω = 2.25 A

Plugging this value in, we can find the voltage drop across R1.

VR1 = IR = (2.25 A)(2Ω) = 4.5 V

Now we can determine the voltage drop across the parallel resistors by subtracting the voltage drop across R1 from the battery.

VA = 9V – 4.5V = 4.5V

Because RA and R4 are in parallel, the voltage drop across R4 is also 4.5V

Example Question #12 : Voltage, Energy, And Power

A circuit consists of a  current passing through a  resistor for . Find the heat generated.

Possible Answers:

Correct answer:

Explanation:

Ohm's Law states that . We are given the current and resistance, allowing us to solve for the voltage.

We also know that . Now that we have the voltage, we can solve for the power.

Finally, we know that . Using this, we can solve for the energy (or work) that is generated by the circuit.

Example Question #12 : Circuits

Suppose you have a circuit with two resistors connected in parallel. The first resistor (resistor A) has a resistance of , whereas the second resistor (resistor B) has a resistance of . Which of the following is true regarding the power dissipated in the two resistors?

Possible Answers:

The relative power dissipation in the two resistors cannot be determined from the given information

Resistor A will have less power dissipation than resistor B

Resistor A will have more power dissipation than resistor B

Resistor A and resistor B will have the same power dissipation

Correct answer:

Resistor A will have less power dissipation than resistor B

Explanation:

Recall that circuit elements (such as resistors) connected in parallel have the same potential difference; therefore, resistor A and resistor B must have the same potential difference. Since we have information about the potential difference and the resistance of the two resistors, it would be best to use the equation for power in terms of voltage and resistance.

Since the potential difference is constant for both resistors, the power will only depend on the resistance. The equation implies that the power decreases when resistance is high; therefore, resistor A will have lower power dissipation than resistor B because resistor A has the greater resistance.

Example Question #11 : Circuits

Consider two resistors connected in series. The resistor with more power dissipation will likely have __________ potential difference and __________ resistance than the resistor with less power dissipation.

Possible Answers:

the same . . . a smaller

a larger . . . a larger

a larger . . . a smaller

the same . . . a larger

Correct answer:

a larger . . . a smaller

Explanation:

Resistors connected in series will have the same current flowing through them, but will have different potential differences. Since we are concerned with the differences in potential difference and resistance, we need to use the power dissipation equation in terms of voltage and resistance:

The equation implies that there will be a greater power dissipation when the potential difference increases and the resistance decreases. A resistor undergoing greater power dissipation will most likely have a higher potential difference and lower resistance.

Example Question #574 : Mcat Physical Sciences

Which of the following is false regarding power dissipation in an electrical circuit?

I. A decrease in power dissipation across a resistor means more of the electrical energy is converted to heat

II. Power dissipation always decreases as the resistance of a resistor increases

III. Electrical power could be measured in units of "volt-amperes"

Possible Answers:

I and II

II and III

III only

I, II, and III

Correct answer:

I and II

Explanation:

Power dissipation is defined as the ability of a circuit element (such as a resistor) to convert the electrical energy to other forms of energy, such as heat or mechanical energy. This means that a decrease in power dissipation will convert less of the electrical energy to heat and mechanical energy. Statement I is false (and therefore a correct answer choice).

Electrical power can be written in terms of voltage () and resistance (), voltage and current (), or resistance and current. Since we are only concerned with the effects of resistance on power dissipation, we will use the equation for power in terms of voltage and resistance, and resistance and current:

Notice that resistance is in the numerator in the first equation and in the denominator in the second equation; therefore, the power doesn’t always decrease when resistance increases. It depends on the equation used to calculate the power. Statement II is false (and therefore a correct answer choice).

Amperes is the unit of current and volts is the unit of voltage; therefore, we need to find the equation for power in terms of voltage and current to determine if power can be measured in volt-amperes. The equation for power in terms of voltage and current is:

Power can be measured in the units of volt-amperes (VA). Statement III is true (and therefore an incorrect answer option).

Example Question #14 : Voltage, Energy, And Power

How much electrical energy is lost per hour in a circuit that has a resistor with a resistance of  and a voltage source that supplies a voltage of ?

Possible Answers:

Correct answer:

Explanation:

The question is asking for the amount of energy lost per unit of time; therefore, we need to solve for the power dissipation. We are given the resistance and the voltage. This means that we use the power dissipation equation in terms of resistance and voltage:

Solving for power gives us:

Recall that watts is the SI unit for power, but it can be also written as Joules per second. Since we are solving for Joules lost per hour, we need to convert our units:

This means that 108J of electrical energy is lost every hour due to power dissipation in the resistor.  

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