Chapter 13 Temperature, Kinetic Theory, and the Gas Laws
- State the ideal gas law in terms of molecules and in terms of moles.
- Use the ideal gas law to calculate pressure change, temperature change, volume change, or the number of molecules or moles in a given volume.
- Use Avogadro’s number to convert between number of molecules and number of moles.
In this section, we continue to explore the thermal behavior of gases. In particular, we examine the characteristics of atoms and molecules that compose gases. (Most gases, for example nitrogen,and oxygen,are composed of two or more atoms. We will primarily use the term “molecule” in discussing a gas because the term can also be applied to monatomic gases, such as helium.)
Gases are easily compressed. We can see evidence of this in [link], where you will note that gases have the largest coefficients of volume expansion. The large coefficients mean that gases expand and contract very rapidly with temperature changes. In addition, you will note that most gases expand at the same rate, or have the sameThis raises the question as to why gases should all act in nearly the same way, when liquids and solids have widely varying expansion rates.
The answer lies in the large separation of atoms and molecules in gases, compared to their sizes, as illustrated in Figure 2. Because atoms and molecules have large separations, forces between them can be ignored, except when they collide with each other during collisions. The motion of atoms and molecules (at temperatures well above the boiling temperature) is fast, such that the gas occupies all of the accessible volume and the expansion of gases is rapid. In contrast, in liquids and solids, atoms and molecules are closer together and are quite sensitive to the forces between them.
To get some idea of how pressure, temperature, and volume of a gas are related to one another, consider what happens when you pump air into an initially deflated tire. The tire’s volume first increases in direct proportion to the amount of air injected, without much increase in the tire pressure. Once the tire has expanded to nearly its full size, the walls limit volume expansion. If we continue to pump air into it, the pressure increases. The pressure will further increase when the car is driven and the tires move. Most manufacturers specify optimal tire pressure for cold tires. (See Figure 3.)
At room temperatures, collisions between atoms and molecules can be ignored. In this case, the gas is called an ideal gas, in which case the relationship between the pressure, volume, and temperature is given by the equation of state called the ideal gas law.
IDEAL GAS LAW
The ideal gas law states that
whereis the absolute pressure of a gas,is the volume it occupies,is the number of atoms and molecules in the gas, andis its absolute temperature. The constantis called the Boltzmann constant in honor of Austrian physicist Ludwig Boltzmann (1844–1906) and has the value
The ideal gas law can be derived from basic principles, but was originally deduced from experimental measurements of Charles’ law (that volume occupied by a gas is proportional to temperature at a fixed pressure) and from Boyle’s law (that for a fixed temperature, the productis a constant). In the ideal gas model, the volume occupied by its atoms and molecules is a negligible fraction ofThe ideal gas law describes the behavior of real gases under most conditions. (Note, for example, thatis the total number of atoms and molecules, independent of the type of gas.)
Let us see how the ideal gas law is consistent with the behavior of filling the tire when it is pumped slowly and the temperature is constant. At first, the pressureis essentially equal to atmospheric pressure, and the volumeincreases in direct proportion to the number of atoms and moleculesput into the tire. Once the volume of the tire is constant, the equationpredicts that the pressure should increase in proportion to the number N of atoms and molecules.
Example 1: Calculating Pressure Changes Due to Temperature Changes: Tire Pressure
Suppose your bicycle tire is fully inflated, with an absolute pressure of(a gauge pressure of just under) at a temperature ofWhat is the pressure after its temperature has risen toAssume that there are no appreciable leaks or changes in volume.
The pressure in the tire is changing only because of changes in temperature. First we need to identify what we know and what we want to know, and then identify an equation to solve for the unknown.
We know the initial pressurethe initial temperatureand the final temperatureWe must find the final pressureHow can we use the equationAt first, it may seem that not enough information is given, because the volumeand number of atomsare not specified. What we can do is use the equation twice:andIf we dividebywe can come up with an equation that allows us to solve for
Since the volume is constant,andare the same and they cancel out. The same is true forandandwhich is a constant. Therefore,
We can then rearrange this to solve for
where the temperature must be in units of kelvins, becauseandare absolute temperatures.
1. Convert temperatures from Celsius to Kelvin.
2. Substitute the known values into the equation.
The final temperature is about 6% greater than the original temperature, so the final pressure is about 6% greater as well. Note that absolute pressure and absolute temperature must be used in the ideal gas law.
MAKING CONNECTIONS: TAKE-HOME EXPERIMENT—REFRIGERATING A BALLOON
Inflate a balloon at room temperature. Leave the inflated balloon in the refrigerator overnight. What happens to the balloon, and why?
Example 2: Calculating the Number of Molecules in a Cubic Meter of Gas
How many molecules are in a typical object, such as gas in a tire or water in a drink? We can use the ideal gas law to give us an idea of how largetypically is.
Calculate the number of molecules in a cubic meter of gas at standard temperature and pressure (STP), which is defined to beand atmospheric pressure.
Because pressure, volume, and temperature are all specified, we can use the ideal gas lawto find
1. Identify the knowns.
2. Identify the unknown: number of molecules,
3. Rearrange the ideal gas law to solve for
4. Substitute the known values into the equation and solve for
This number is undeniably large, considering that a gas is mostly empty space.is huge, even in small volumes. For example,of a gas at STP hasmolecules in it. Once again, note thatis the same for all types or mixtures of gases.
Moles and Avogadro’s Number
It is sometimes convenient to work with a unit other than molecules when measuring the amount of substance. A mole (abbreviated mol) is defined to be the amount of a substance that contains as many atoms or molecules as there are atoms in exactly 12 grams (0.012 kg) of carbon-12. The actual number of atoms or molecules in one mole is called Avogadro’s numberin recognition of Italian scientist Amedeo Avogadro (1776–1856). He developed the concept of the mole, based on the hypothesis that equal volumes of gas, at the same pressure and temperature, contain equal numbers of molecules. That is, the number is independent of the type of gas. This hypothesis has been confirmed, and the value of Avogadro’s number is
One mole always containsparticles (atoms or molecules), independent of the element or substance. A mole of any substance has a mass in grams equal to its molecular mass, which can be calculated from the atomic masses given in the periodic table of elements.
Check Your Understanding 1
The active ingredient in a Tylenol pill is 325 mg of acetaminophenFind the number of active molecules of acetaminophen in a single pill.
Example 3: Calculating Moles per Cubic Meter and Liters per Mole
Calculate: (a) the number of moles inof gas at STP, and (b) the number of liters of gas per mole.
Strategy and Solution
(a) We are asked to find the number of moles per cubic meter, and we know from Example 2 that the number of molecules per cubic meter at STP isThe number of moles can be found by dividing the number of molecules by Avogadro’s number. We letstand for the number of moles,
(b) Using the value obtained for the number of moles in a cubic meter, and converting cubic meters to liters, we obtain
This value is very close to the accepted value of 22.4 L/mol. The slight difference is due to rounding errors caused by using three-digit input. Again this number is the same for all gases. In other words, it is independent of the gas.
The (average) molar weight of air (approximately 80%and 20%isThus the mass of one cubic meter of air is 1.28 kg. If a living room has dimensionsthe mass of air inside the room is 96 kg, which is the typical mass of a human.
Check Your Understanding 2
The density of air at standard conditionsandisAt what pressure is the densityif the temperature and number of molecules are kept constant?
The Ideal Gas Law Restated Using Moles
A very common expression of the ideal gas law uses the number of moles,rather than the number of atoms and molecules,We start from the ideal gas law,
and multiply and divide the equation by Avogadro’s numberThis gives
Note thatis the number of moles. We define the universal gas constantand obtain the ideal gas law in terms of moles.
IDEAL GAS LAW (IN TERMS OF MOLES)
The ideal gas law (in terms of moles) is
The numerical value ofin SI units is
In other units,
You can use whichever value ofis most convenient for a particular problem.
Example 4: Calculating Number of Moles: Gas in a Bike Tire
How many moles of gas are in a bike tire with a volume ofa pressure of(a gauge pressure of just under), and at a temperature of
Identify the knowns and unknowns, and choose an equation to solve for the unknown. In this case, we solve the ideal gas law,for the number of moles
1. Identify the knowns.
2. Rearrange the equation to solve forand substitute known values.
The most convenient choice forin this case isbecause our known quantities are in SI units. The pressure and temperature are obtained from the initial conditions in Example 1, but we would get the same answer if we used the final values.
The ideal gas law can be considered to be another manifestation of the law of conservation of energy (see Chapter 7.6 Conservation of Energy). Work done on a gas results in an increase in its energy, increasing pressure and/or temperature, or decreasing volume. This increased energy can also be viewed as increased internal kinetic energy, given the gas’s atoms and molecules.
The Ideal Gas Law and Energy
Let us now examine the role of energy in the behavior of gases. When you inflate a bike tire by hand, you do work by repeatedly exerting a force through a distance. This energy goes into increasing the pressure of air inside the tire and increasing the temperature of the pump and the air.
The ideal gas law is closely related to energy: the units on both sides are joules. The right-hand side of the ideal gas law inisThis term is roughly the amount of translational kinetic energy ofatoms or molecules at an absolute temperatureas we shall see formally in Chapter 13.4 Kinetic Theory: Atomic and Molecular Explanation of Pressure and Temperature. The left-hand side of the ideal gas law iswhich also has the units of joules. We know from our study of fluids that pressure is one type of potential energy per unit volume, so pressure multiplied by volume is energy. The important point is that there is energy in a gas related to both its pressure and its volume. The energy can be changed when the gas is doing work as it expands—something we explore in Chapter 14 Heat and Heat Transfer Methods—similar to what occurs in gasoline or steam engines and turbines.
PROBLEM-SOLVING STRATEGY: THE IDEAL GAS LAW
Step 1 Examine the situation to determine that an ideal gas is involved. Most gases are nearly ideal.
Step 2 Make a list of what quantities are given, or can be inferred from the problem as stated (identify the known quantities). Convert known values into proper SI units (K for temperature, Pa for pressure,for volume, molecules forand moles for).
Step 3 Identify exactly what needs to be determined in the problem (identify the unknown quantities). A written list is useful.
Step 4 Determine whether the number of molecules or the number of moles is known, in order to decide which form of the ideal gas law to use. The first form isand involvesthe number of atoms or molecules. The second form isand involvesthe number of moles.
Step 5 Solve the ideal gas law for the quantity to be determined (the unknown quantity). You may need to take a ratio of final states to initial states to eliminate the unknown quantities that are kept fixed.
Step 6 Substitute the known quantities, along with their units, into the appropriate equation, and obtain numerical solutions complete with units. Be certain to use absolute temperature and absolute pressure.
Step 7 Check the answer to see if it is reasonable: Does it make sense?
Check Your Understanding 3
Liquids and solids have densities about 1000 times greater than gases. Explain how this implies that the distances between atoms and molecules in gases are about 10 times greater than the size of their atoms and molecules.
- The ideal gas law relates the pressure and volume of a gas to the number of gas molecules and the temperature of the gas.
- The ideal gas law can be written in terms of the number of molecules of gas:
whereis pressure,is volume,is temperature,is number of molecules, andis the Boltzmann constant
- A mole is the number of atoms in a 12-g sample of carbon-12.
- The number of molecules in a mole is called Avogadro’s number
- A mole of any substance has a mass in grams equal to its molecular weight, which can be determined from the periodic table of elements.
- The ideal gas law can also be written and solved in terms of the number of moles of gas:
whereis number of moles andis the universal gas constant,
- The ideal gas law is generally valid at temperatures well above the boiling temperature.
1: Find out the human population of Earth. Is there a mole of people inhabiting Earth? If the average mass of a person is 60 kg, calculate the mass of a mole of people. How does the mass of a mole of people compare with the mass of Earth?
2: Under what circumstances would you expect a gas to behave significantly differently than predicted by the ideal gas law?
3: A constant-volume gas thermometer contains a fixed amount of gas. What property of the gas is measured to indicate its temperature?
Problems & Exercises
1: The gauge pressure in your car tires isat a temperature ofwhen you drive it onto a ferry boat to Alaska. What is their gauge pressure later, when their temperature has dropped to
2: Convert an absolute pressure ofto gauge pressure in(This value was stated to be just less thanin Example 4. Is it?)
3: Suppose a gas-filled incandescent light bulb is manufactured so that the gas inside the bulb is at atmospheric pressure when the bulb has a temperature of(a) Find the gauge pressure inside such a bulb when it is hot, assuming its average temperature is(an approximation) and neglecting any change in volume due to thermal expansion or gas leaks. (b) The actual final pressure for the light bulb will be less than calculated in part (a) because the glass bulb will expand. What will the actual final pressure be, taking this into account? Is this a negligible difference?
4: Large helium-filled balloons are used to lift scientific equipment to high altitudes. (a) What is the pressure inside such a balloon if it starts out at sea level with a temperature ofand rises to an altitude where its volume is twenty times the original volume and its temperature is(b) What is the gauge pressure? (Assume atmospheric pressure is constant.)
5: Confirm that the units ofare those of energy for each value of(a)(b)and (c)
6: In the text, it was shown thatfor gas at STP. (a) Show that this quantity is equivalent toas stated. (b) About how many atoms are there in one(a cubic micrometer) at STP? (c) What does your answer to part (b) imply about the separation of atoms and molecules?
7: Calculate the number of moles in the 2.00-L volume of air in the lungs of the average person. Note that the air is at(body temperature).
8: An airplane passenger hasof air in his stomach just before the plane takes off from a sea-level airport. What volume will the air have at cruising altitude if cabin pressure drops to
9: (a) What is the volume (in) of Avogadro’s number of sand grains if each grain is a cube and has sides that are 1.0 mm long? (b) How many kilometers of beaches in length would this cover if the beach averages 100 m in width and 10.0 m in depth? Neglect air spaces between grains.
10: An expensive vacuum system can achieve a pressure as low asatHow many atoms are there in a cubic centimeter at this pressure and temperature?
11: The number density of gas atoms at a certain location in the space above our planet is aboutand the pressure isin this space. What is the temperature there?
12: A bicycle tire has a pressure ofat a temperature ofand contains 2.00 L of gas. What will its pressure be if you let out an amount of air that has a volume ofat atmospheric pressure? Assume tire temperature and volume remain constant.
13: A high-pressure gas cylinder contains 50.0 L of toxic gas at a pressure ofand a temperature ofIts valve leaks after the cylinder is dropped. The cylinder is cooled to dry ice temperatureto reduce the leak rate and pressure so that it can be safely repaired. (a) What is the final pressure in the tank, assuming a negligible amount of gas leaks while being cooled and that there is no phase change? (b) What is the final pressure if one-tenth of the gas escapes? (c) To what temperature must the tank be cooled to reduce the pressure to 1.00 atm (assuming the gas does not change phase and that there is no leakage during cooling)? (d) Does cooling the tank appear to be a practical solution?
14: Find the number of moles in 2.00 L of gas atand underof pressure.
15: Calculate the depth to which Avogadro’s number of table tennis balls would cover Earth. Each ball has a diameter of 3.75 cm. Assume the space between balls adds an extra 25.0% to their volume and assume they are not crushed by their own weight.
16: (a) What is the gauge pressure in acar tire containing 3.60 mol of gas in a 30.0 L volume? (b) What will its gauge pressure be if you add 1.00 L of gas originally at atmospheric pressure andAssume the temperature returns toand the volume remains constant.
17: (a) In the deep space between galaxies, the density of atoms is as low asand the temperature is a frigid 2.7 K. What is the pressure? (b) What volume (in) is occupied by 1 mol of gas? (c) If this volume is a cube, what is the length of its sides in kilometers?
- ideal gas law
- the physical law that relates the pressure and volume of a gas to the number of gas molecules or number of moles of gas and the temperature of the gas
- Boltzmann constant
- a physical constant that relates energy to temperature;
- Avogadro’s number
- the number of molecules or atoms in one mole of a substance;
- the quantity of a substance whose mass (in grams) is equal to its molecular mass
Check Your Understanding 1
We first need to calculate the molar mass (the mass of one mole) of acetaminophen. To do this, we need to multiply the number of atoms of each element by the element’s atomic mass.
Then we need to calculate the number of moles in 325 mg.
Then use Avogadro’s number to calculate the number of molecules.
Check Your Understanding 2
The best way to approach this question is to think about what is happening. If the density drops to half its original value and no molecules are lost, then the volume must double. If we look at the equationwe see that when the temperature is constant, the pressure is inversely proportional to volume. Therefore, if the volume doubles, the pressure must drop to half its original value, and
Check Your Understanding 3
Atoms and molecules are close together in solids and liquids. In gases they are separated by empty space. Thus gases have lower densities than liquids and solids. Density is mass per unit volume, and volume is related to the size of a body (such as a sphere) cubed. So if the distance between atoms and molecules increases by a factor of 10, then the volume occupied increases by a factor of 1000, and the density decreases by a factor of 1000.
Problems & Exercises
(a) 0.136 atm
(b) 0.135 atm. The difference between this value and the value from part (a) is negligible.
(c) 2.16 K
(d) No. The final temperature needed is much too low to be easily achieved for a large object.