13.4 Kinetic theory: atomic and molecular explanation of pressure

College physics Page 1 / 5

Express the ideal gas law in terms of molecular mass and velocity.
Define thermal energy.
Calculate the kinetic energy of a gas molecule, given its temperature.
Describe the relationship between the temperature of a gas and the kinetic energy of atoms and molecules.
Describe the distribution of speeds of molecules in a gas.

We have developed macroscopic definitions of pressure and temperature. Pressure is the force divided by the area on which the force is exerted, and temperature is measured with a thermometer. We gain a better understanding of pressure and temperature from the kinetic theory of gases, which assumes that atoms and molecules are in continuous random motion.

A green vector v, representing a molecule colliding with a wall, is pointing at the surface of a wall at an angle. A second vector v primed starts at the point of impact and travels away from the wall at an angle. A dotted line perpendicular to the wall through the point of impact represents the component of the molecule’s momentum that is perpendicular to the wall. A red vector F is pointing into the wall from the point of impact, representing the force of the molecule hitting the wall. — When a molecule collides with a rigid wall, the component of its momentum perpendicular to the wall is reversed. A force is thus exerted on the wall, creating pressure.

[link] shows an elastic collision of a gas molecule with the wall of a container, so that it exerts a force on the wall (by Newton’s third law). Because a huge number of molecules will collide with the wall in a short time, we observe an average force per unit area. These collisions are the source of pressure in a gas. As the number of molecules increases, the number of collisions and thus the pressure increase. Similarly, the gas pressure is higher if the average velocity of molecules is higher. The actual relationship is derived in the Things Great and Small feature below. The following relationship is found:

PV = \frac{1}{3} Nm \bar{v^{2}},

where $P$ is the pressure (average force per unit area), $V$ is the volume of gas in the container, $N$ is the number of molecules in the container, $m$ is the mass of a molecule, and $\bar{v^{2}}$ is the average of the molecular speed squared.

What can we learn from this atomic and molecular version of the ideal gas law? We can derive a relationship between temperature and the average translational kinetic energy of molecules in a gas. Recall the previous expression of the ideal gas law:

PV = NkT .

Equating the right-hand side of this equation with the right-hand side of $PV = \frac{1}{3} Nm \bar{v^{2}}$ gives

\frac{1}{3} Nm \bar{v^{2}} = NkT .

Making connections: things great and small—atomic and molecular origin of pressure in a gas

[link] shows a box filled with a gas. We know from our previous discussions that putting more gas into the box produces greater pressure, and that increasing the temperature of the gas also produces a greater pressure. But why should increasing the temperature of the gas increase the pressure in the box? A look at the atomic and molecular scale gives us some answers, and an alternative expression for the ideal gas law.

The figure shows an expanded view of an elastic collision of a gas molecule with the wall of a container. Calculating the average force exerted by such molecules will lead us to the ideal gas law, and to the connection between temperature and molecular kinetic energy. We assume that a molecule is small compared with the separation of molecules in the gas, and that its interaction with other molecules can be ignored. We also assume the wall is rigid and that the molecule’s direction changes, but that its speed remains constant (and hence its kinetic energy and the magnitude of its momentum remain constant as well). This assumption is not always valid, but the same result is obtained with a more detailed description of the molecule’s exchange of energy and momentum with the wall.

Diagram representing the pressures that a gas exerts on the walls of a box in a three-dimensional coordinate system with x, y, and z components. — Gas in a box exerts an outward pressure on its walls. A molecule colliding with a rigid wall has the direction of its velocity and momentum in the $x$ -direction reversed. This direction is perpendicular to the wall. The components of its velocity momentum in the $y$ - and $z$ -directions are not changed, which means there is no force parallel to the wall.

If the molecule’s velocity changes in the $x$ -direction, its momentum changes from $- {mv}_{x}$ to $+ {mv}_{x}$ . Thus, its change in momentum is $Δ mv = + {mv}_{x} - (- {mv}_{x}) = 2 {mv}_{x}$ . The force exerted on the molecule is given by

F = \frac{Δ p}{Δ t} = \frac{2 {mv}_{x}}{Δ t} .

There is no force between the wall and the molecule until the molecule hits the wall. During the short time of the collision, the force between the molecule and wall is relatively large. We are looking for an average force; we take $Δ t$ to be the average time between collisions of the molecule with this wall. It is the time it would take the molecule to go across the box and back (a distance $2 l)$ at a speed of $v_{x}$ . Thus $Δ t = 2 l / v_{x}$ , and the expression for the force becomes

F = \frac{2 {mv}_{x}}{2 l / v_{x}} = \frac{{mv}_{x}^{2}}{l} .

This force is due to one molecule. We multiply by the number of molecules $N$ and use their average squared velocity to find the force

F = N \frac{m \bar{v_{x}^{2}}}{l},

where the bar over a quantity means its average value. We would like to have the force in terms of the speed $v$ , rather than the $x$ -component of the velocity. We note that the total velocity squared is the sum of the squares of its components, so that

\bar{v^{2}} = \bar{v_{x}^{2}} + \bar{v_{y}^{2}} + \bar{v_{z}^{2}} .

Because the velocities are random, their average components in all directions are the same:

\bar{v_{x}^{2}} = \bar{v_{y}^{2}} = \bar{v_{z}^{2}} .

Thus,

\bar{v^{2}} = 3 \bar{v_{x}^{2}},

\bar{v_{x}^{2}} = \frac{1}{3} \bar{v^{2}} .

Substituting $\frac{1}{3} \bar{v^{2}}$ into the expression for $F$ gives

F = N \frac{m \bar{v^{2}}}{3 l} .

The pressure is $F / A,$ so that we obtain

P = \frac{F}{A} = N \frac{m \bar{v^{2}}}{3 Al} = \frac{1}{3} \frac{Nm \bar{v^{2}}}{V},

where we used $V = Al$ for the volume. This gives the important result.

PV = \frac{1}{3} Nm \bar{v^{2}}

This equation is another expression of the ideal gas law.

Questions & Answers

A golfer on a fairway is 70 m away from the green, which sits below the level of the fairway by 20 m. If the golfer hits the ball at an angle of 40° with an initial speed of 20 m/s, how close to the green does she come?

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A mouse of mass 200 g falls 100 m down a vertical mine shaft and lands at the bottom with a speed of 8.0 m/s. During its fall, how much work is done on the mouse by air resistance

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Chemistry is a branch of science that deals with the study of matter,it composition,it structure and the changes it undergoes

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2. A sled plus passenger with total mass 50 kg is pulled 20 m across the snow (0.20) at constant velocity by a force directed 25° above the horizontal. Calculate (a) the work of the applied force, (b) the work of friction, and (c) the total work.

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you have been hired as an espert witness in a court case involving an automobile accident. the accident involved car A of mass 1500kg which crashed into stationary car B of mass 1100kg. the driver of car A applied his brakes 15 m before he skidded and crashed into car B. after the collision, car A s

Samuel Reply

can someone explain to me, an ignorant high school student, why the trend of the graph doesn't follow the fact that the higher frequency a sound wave is, the more power it is, hence, making me think the phons output would follow this general trend?

Joseph Reply

Nevermind i just realied that the graph is the phons output for a person with normal hearing and not just the phons output of the sound waves power, I should read the entire thing next time

Joseph

Follow up question, does anyone know where I can find a graph that accuretly depicts the actual relative "power" output of sound over its frequency instead of just humans hearing

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"Generation of electrical energy from sound energy | IEEE Conference Publication | IEEE Xplore" ***ieeexplore.ieee.org/document/7150687?reload=true

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A string is 3.00 m long with a mass of 5.00 g. The string is held taut with a tension of 500.00 N applied to the string. A pulse is sent down the string. How long does it take the pulse to travel the 3.00 m of the string?

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Source: OpenStax, College physics. OpenStax CNX. Jul 27, 2015 Download for free at http://legacy.cnx.org/content/col11406/1.9

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