Properties of Ideal Gases - AP Physics 2

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Question

Which of the following is not a property of an ideal gas?

Answer

Ideal gases have particles that are considered to be point masses. This means that all of their (extremely small) mass is contained in a single, infinitesimal point of zero volume. These particles experience elastic collisions, which means they lose no kinetic energy when they collide with other particles. If the particles experienced strong intermolecular forces, then they couldn't have elastic collisions, so they wouldn't be ideal gases anymore. Ideal gases don't experience any intermolecular forces.

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Question

A real gas becomes more like an ideal gas at temperatures and pressures.

Answer

When the temperature is higher, the kinetic energy of particles is higher. Because their energy is higher, they bounce more energetically, letting them ignore most intermolecular forces (which is something ideal gases don't experience).

An important assumption for ideal gases is that the volume of the particles is negligible compared to the volume of their container. For real gases, as pressure increases, the particles get closer together, and their volume gets less negligible when compared to the volume of the container. This is why real gases behave more ideally at lower pressures.

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Question

What is the temperature in Kelvin for 1mol of gas at 5atm and a volume of 10L?

$1{ atm}= 101.3{ kPa}= 101325 \frac{{N}}{{m}^2}$

$R= 8.314{ }\frac{{L}\cdot {kPa}}{{mol} \cdot {K}}$

Answer

Use the ideal gas law equation.

Manipulate the equation, substitute the givens, and solve for temperature. Write the gas constants necessary to solve the problem.

$T=\frac{PV}{nR}$

$1{ atm}= 101.3{ kPa}= 101325 \frac{{N}}{{m}^2}$

$R= 8.314{ }\frac{{L}\cdot {kPa}}{{mol} \cdot {K}}$

$T=\frac{PV}{nR}= \frac{(5{ atm})(\frac{101.3{ kPa}}{1{ atm}})(10{ L})}{(1{ mol})(8.314{ }\frac{{L}\cdot {kPa}}{{mol} \cdot {K}})}$

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Question

Which of the following is the correct formula to find the internal energy of an ideal gas?

Answer

An ideal gas has no molecular interactions besides perfectly elastic collisions. The energy is the combined kinetic energies of ideal gas molecules since there is no potential energy. For point molecules of the monatomic gas, the equation can be written as:

$U=\frac{3}{2}NkT$

Note that $K_{{avg}}=\frac{3}{2}kT$ is the equation for average kinetic energy also in Joules.

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Question

You are at the top of Mt. Whitney holding onto a balloon of volume . The temperature is $19^{\circ}C$ , and the air pressure is . You then drive to Death Valley, where the temperature is $35 ^{\circ}C$ , and the air pressure is . What is the new volume of the balloon?

Answer

We will use the combined gas law:

$\frac{P_1 V_1}{T_1}=\frac{P_2 V_2}{T_2}$

With "1" referring to Mt Whitney, and "2" referring to Death Valley, we can rearrange the equation to get

$\frac{P_1 V_1 T_2}{T_1 P_2}=V_2$

We need to convert both temperatures to Kelvin

$19^{\circ}C+273=292^{\circ}K$

$35^{\circ}C+273=308^{\circ}K$

We plug in our values.

$\frac{.83 \cdot1.12\cdot 308}{292\cdot 1.11}=V_2$

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Question

We have of oxygen gas at $19^\circ C$ . We increase the temperature to $38 ^\circ C$ and keep the pressure the same. What is the new volume?

Answer

We will use the relationship:

$\frac{V_1}{T_1}=\frac{V_2}{T_2}$

Rearrange for the final volume:

$\frac{V_1 T_2}{T_1}={V_2}$

Convert our temperatures to kelvin.

$19^{\circ}C+273=292^{\circ}K$

$38^{\circ}C+273=311^{\circ}K$

Plug in our values and solve.

$\frac{V_1 T_2}{T_1}={V_2}$

$\frac{10L* 292^{\circ}K}{311^{\circ}K}={V_2}$

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Question

We have of gas at $10 ^\circ C$ . We increase the temperature to $30 ^\circ C$ , while keeping the pressure constant. What is the new volume?

Answer

We will use the relationship:

$\frac{V_1}{T_1}=\frac{V_2}{T_2}$

Rearrange to solve for the final volume:

$\frac{V_1 T_2}{T_1}={V_2}$

Convert our temperatures to kelvin:

$10^{\circ}C+273=283^{\circ}K$

$30^{\circ}C+273=303^{\circ}K$

Plug in our values and solve.

$\frac{15L* 303^{\circ}K}{283^{\circ}K}={V_2}$

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Question

We have of helium gas at . We decrease the pressure to , while keeping the temperature the same. What is the new volume?

Answer

We will use the relationship:

Rearrange to solve for the final volume:

$\frac{P_1V_1}{P_2}=V_2$

Plug in our values and solve.

$\frac{1.3atm*13L}{.85atm}=V_2$

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Question

We have of neon gas at . We increase the pressure to while keeping the temperature constant. What is the new volume?

Answer

We will use the relationship:

Rearrange to solve for the final volume:

$\frac{P_1V_1}{P_2}=V_2$

Plug in our values and solve.

$\frac{.5atm*6L}{1.5atm}=V_2$

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Question

We have of neon gas. We increase the temperature from $10 ^\circ C$ to $50 ^\circ C$ , and increase the pressure from to . What will be the new volume?

Answer

First, we will convert celsius to Kelvin.

$10^{\circ}C+273=283^{\circ}K$

$50^{\circ}C+273=323^{\circ}K$

Then, we will use the relationship:

$\frac{P_1 V_1}{T_1}=\frac{P_2 V_2}{T_2}$

Solve for volume final volume:

$\frac{P_1 V_1 T_2}{T_1 P_2}=V_2$

Plug in our values and solve.

$\frac{1atm* 16L323^{\circ}K}{283^{\circ}K 5atm}=V_2$

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Question

Under which of the following conditions would a gas be expected to deviate the least from ideal behavior?

Answer

When talking about gases, it's convenient to talk about gases that behave ideally. The ideal gas law, , generally only holds true for gases that behave ideally. Once gases begin to deviate from ideal behavior, this equation begins to lose its accuracy in its power to predict.

There are a number of assumptions that are made when referring to gases that behave ideally, and these assumptions constitute what is known as the kinetic molecular theory of gases. In this model, there are a total of 5 assumptions:

1. Individual gas particles are very tiny points of mass that essentially have no volume (i.e. the volume of a gas is equal to the volume of free space in the container).

2. These gas particles are neither attracted to, nor repelled by, other gas particles (i.e. there are no intermolecular forces acting between gas particles).

3. Each of these gas particles are continuously moving in random directions.

4. All of these gas particles collide with each other, such that no energy is gained or lost by each collision (i.e. each collision is completely elastic).

5. At a given temperature, the average kinetic energy for a given sample of gas is the same as any gas (i.e. the identity of the gas does not matter) and the average kinetic energy of the sample of gas is directly related to the absolute temperature.

Now that we know what the assumptions are, let's go ahead and see how pressure and temperature affect ideal behavior, since these two parameters show up in each of the answer choices.

Temperature

When the temperature of a gas is lowered, the average kinetic energy of the sample of gas also decreases. Consequently, each gas particle making up the solution is expected to slow down. When this happens, the gas particles become more available for interacting with other gas particles, which increases the likelihood for intermolecular forces to begin playing a role. This violates one of the assumptions of kinetic molecular theory. When individual gas particles begin to attract one another, the pressure that the gas exerts on the wall of its container becomes less than what the ideal gas law equation would predict.

Thus, we would expect a high temperature to cause the least deviation from ideal behavior. In other words, a high temperature would increase the average kinetic energy of the sample of gas, and when all of the gas particles are shooting around at greater speeds, they have less of an opportunity to interact with other gas particles.

Pressure

When the pressure of a gas is increased, we also see deviations from ideal behavior. Remember that one of the assumptions of kinetic molecular theory is that the individual gas particles are very tiny points of mass that essentially have no volume, which means that the volume of the gas as predicted by the ideal gas law is essentially equal to the volume of the container. But, we of course know that real gases do not have zero volume and instead, each individual gas particle takes up a small amount of volume. As the external pressure becomes greater and greater, the volume of the container decreases as well. This, in turn, causes each gas particle to comprise a greater fraction of the container. Consequently, at high enough pressures, a real gas will take up a significant fraction of the container's volume, meaning that the volume of the real gas will be greater than what is predicted by the ideal gas law.

When external pressures are kept low, the volume of the container is sufficiently large enough that the volume of gas takes up a negligible fraction of the container. Thus, low external pressures will be expected to cause the least deviation from the ideal gas law.

In summary, it's important to remember the following:

At high pressures, the actual volume of gas particles makes the real volume higher than the predicted volume.

At low temperatures, intermolecular forces make the actual pressure lower than the predicted pressure.

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Question

Determine the average velocity of radon gas atoms at $35\ ^\circ \textup{C}$

$\textup{R}=8.314\ \frac{\textup{J}}{\textup{mol}\cdot \textup{K}}$

Answer

Using the equation for the root-mean-square speed:

$v=\sqrt{\frac{3RT}{M}}$

$\textup{R}=8.314\ \frac{\textup{J}}{\textup{mol}\cdot \textup{K}}$

is the temperature in Kelvin

is the molar mass of the gas, in kilograms per mole

Converting Celsius to Kelvin and plugging in values:

$v=\sqrt{\frac{38.314308}{.222}}$

$v=186.3\frac{m}{s}$

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Question

In an enclosed space capsule, the temperature increases from $13^\circ C$ to $27^\circ C$ . Determine the ratio of the final to initial pressures: $\frac{P_{final}}{P_{initial}}$ .

Answer

Convert to

Use Gay-Lussac's law:

$\frac{P_1}{T_1}=\frac{P_2}{T_2}$

Plug in values:

$\frac{P_1}{286}=\frac{P_2}{300}$

$\frac{P_2}{P_1}=1.05$

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Question

Determine the average velocity of helium gas atoms at $-5^\circ \textup{C}$ .

$R=8.314\ \frac{\textup{J}}{\textup{mol}\cdot \textup{K}}$

Answer

Use the following equation to find the average velocity:

$v=\sqrt{\frac{3RT}{M}}$

Where $R=8.314\ \frac{\textup{J}}{\textup{mol}\cdot \textup{K}}$

is the temperature in Kelvin

is the molar mass of the gas, in kilograms

Converting Celsius to Kelvin and plugging in values:

$v=\sqrt{\frac{38.314268}{.004}}$

$v=1293\ \frac{\textup{m}}{\textup{s}}$

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Question

A balloon is filled with nitrogen at a temperature of $15\ ^{\circ}C$ to a pressure of $1\textup{ atm}$ . If the temperature is increased to $25\ ^{\circ}C$ and the pressure is increased to $1.5\textup{ atm}$ , by what factor does the density of the nitrogen increase by?

Answer

We will start with the ideal gas law for this problem:

Since the problem statement is asking us for a change in density, we will need to manipulate the ideal gas law to get this unit. We will start by multiplying both sides of the expression by the molecular weight of nitrogen:

Now rearranging we get:

$\frac{m}{V}=\rho = \frac{P(MW)}{RT}$

We can apply this to both scenarios, with density, pressure, and temperature being the only changing variables:

$\rho_1 = \frac{P_1(MW)}{RT_1}$

$\rho_2 = \frac{P_2(MW)}{RT_2}$

Dividing the second expression by the first and eliminating common variables, we get:

$\frac{\rho_2}{\rho_1} = \frac{\frac{P_2}{t_2}}{\frac{P_1}{T_1}} = \frac{P_2T_1}{P_1T_2}$

Plugging in our values and making sure our temperatures are in Kelvin, we get:

$\frac{\rho_2}{\rho_1} = \frac{(1.5atm)(288C)}{(1atm)(298C)}$

$\frac{\rho_2}{\rho_1} = 1.45$

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Question

How would raising the temperature from $5^\circ C$ to $10^\circ C$ change the average velocity of gas molecules?

Answer

Using

$v=\sqrt{\frac{3RT}{M_m}}$

is the temperature in Kelvin

is the gas constant

is the molar mass in kilograms

Converting to Kelvin:

$5^\circ C=278^\circ K$

$10^\circ C=283^\circ K$

It can be seen that this increase in temperature would lead to a very modest increase in velocity.

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Question

Determine the average velocity of chlorine molecules at $35^\circ C$ .

Answer

Using

$v=\sqrt{\frac{3RT}{M_m}}$

is the temperature in Kelvin

is the gas constant

is the molar mass in kilograms

Converting to Kelvin and plugging in values:

$v=\sqrt{\frac{38.314308}{.0709}}$

$v=329\frac{m}{s}$

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Question

Determine the root mean square velocity of oxygen gas at $0^\circ C$

Answer

Using,

$v_{rms}=\sqrt{\frac{3kT}{m}}$

Where

is the Boltzmann constant, $1.3810^{-23}\frac{J}{^\circ K}$

is the temperature, in Kelvin

is the mass of a single molecule, in kilograms

Finding mass of a single oxygen molecule:

$\frac{32grams}{mole}\frac{1 mole}{6.0210^{23} molecules}\frac{1kg}{1000g}=5.3210^{-26}\frac{kg}{molecule}$

Plugging in values:

$v_{rms}=\sqrt{\frac{31.3810^{-23}273}{5.32*10^{-26}}}$

$v_{rms}=460\frac{m}{s}$

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Question

Determine the root mean square velocity of chlorine gas at $150^\circ C$ .

$k=1.38*10^{-23}\frac{J}{^\circ K}$

Answer

Using,

$v_{rms}=\sqrt{\frac{3kT}{m}}$

Where

is the Boltzmann constant, $1.3810^{-23}\frac{J}{^\circ K}$

is the temperature, in Kelvin

is the mass of a single molecule, in kilograms

Finding mass of a single chlorine molecule:

$\frac{70.9grams}{mole}\frac{1 mole}{6.0210^{23} molecules}\frac{1kg}{1000g}=1.1810^{-25}\frac{kg}{molecule}$

Plugging in values:

$v_{rms}=\sqrt{\frac{31.3810^{-23}423}{1.18*10^{-25}}}$

$v_{rms}=385\frac{m}{s}$

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Question

The concept of an ideal gas is useful when using equations to predict the behavior of gasses under a variety of conditions. However, many gasses do not demonstrate ideal behavior. Which of the following is a characteristic of a gas that is not ideal?

Answer

For this question, we're asked to identify a statement that is false with respect to ideal gasses. Let's look at each.

There are a number of assumptions that are put into place when defining an ideal gas, together which are called the kinetic molecular theory of ideal gasses.

For one, each gas particle is assumed to exert no attractive or repulsive forces with any other gas particle. As these particles move in constant motion, they continuously collide both with themselves and with the wall of their container. Each of these collisions is assumed to be perfectly elastic, such that no energy is lost or gained from the collision and energy is perfectly maintained. Furthermore, the size of the individual gas particles is assumed to be so tiny as to be negligible. What this means is that the overall amount of space taken up by the gas particles is negligible with respect to the amount of space in the container.

Although the volume of each gas particle is assumed to be negligible, the same cannot be said about their mass. Each particle has a characteristic mass that is dependent on the identity of the gas.

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