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For an ideal gas where the pressure and temperature are held constant, which of the following is the correct proportionality relation between the volume π of the gas and the number of moles π?
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(A) π is proportional to π squared.
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(B) π is proportional to π.
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(C) π is proportional to the square root of π.
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(D) π is proportional to one divided by π.
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Or (E) π is proportional to one divided by π squared.
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Here, weβre considering an ideal gas, which means weβre approximating that the molecules of this gas donβt interact with each other and that they have negligible size.
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Letβs recall that any ideal gas will obey the formula ππ equals ππ
π, where π is the pressure of the gas, π is its volume, π is the number of moles, π
is the molar gas constant, and π is its absolute temperature.
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This formula is known as the ideal gas law.
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And in this question weβll use it to devise a proportionality relation between the volume and the number of moles of the gas.
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To do this, we can first replace the equal sign with this symbol, which means βis proportional to.β
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Remember that a statement of proportionality helps us understand how variables change with respect to each other.
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So, when we write it out, it should not include any constants because we know those values donβt change.
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For this reason, weβll basically ignore any constant term by setting it equal to one, since a factor of one has no impact on overall value.
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Now, we know that π
represents the molar gas constant, so itβll be excluded from this relationship.
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And although π and π do appear as variables in the ideal gas law itself, remember that weβve been told that this gas has a constant pressure and temperature.
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So weβll leave those terms out as well.
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Thus, the only two true variables that weβre concerned with are π and π.
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So the relationship reads π is proportional to π.
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And we can see right away that this agrees with answer choice (B).
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Another way to say this is π is directly proportional to π because a change in one value corresponds to the same magnitude change for the other value.
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For instance, if we were to increase the volume of the gas by a factor of three, with pressure and temperature held constant, the number of moles must also increase by a factor of three.
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But we could not say the same thing if any of these other relationships were true.
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Notice that in all the other answer choices, π has a different exponent.
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In option (A), π is raised to the second power.
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In (C), we can say π is raised to the one-half.
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(D) shows π to the negative one, and (E) is π to the negative two.
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Thus, for any of these relationships, a change in π would not correspond to the same magnitude of change in π.
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But we know this isnβt the case, since in the actual ideal gas law, π and π are simply π and π.
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Neither term has some other exponent.
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Therefore, weβve seen that the ideal gas law has a direct proportionality between volume and the number of moles.
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So we know that answer choice (B) is correct.
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For an ideal gas with constant pressure and temperature, π is proportional to π.