The Ideal Gas Law

The active ingredient in a Tylenol pill is 325 mg of acetaminophen $({\text{C}}_8{\text{H}}_9{\text{NO}}_2)$

. Find the number of active molecules of acetaminophen in a single pill.

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.

The density of air at standard conditions $(P=1\text{atm}$

and $T=\text{20}\text{º}\text{C})$

is $1\text{.}\text{28}{\text{kg/m}}^3$

. At what pressure is the density $0\text{.}{\text{64 kg/m}}^3$

if the temperature and number of molecules are kept constant?

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 equation $\text{PV}=\text{NkT}$

, we 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 $P_{\text{f}}=0\text{.}\text{50}\text{atm}\text{.}$

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.

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.

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?

Under what circumstances would you expect a gas to behave significantly differently than predicted by the ideal gas law?

A constant-volume gas thermometer contains a fixed amount of gas. What property of the gas is measured to indicate its temperature?

The gauge pressure in your car tires is $2\text{.}\text{50}\times {\text{10}}^5{\text{N/m}}^2$

at a temperature of $\text{35}\text{.}0\text{º}\text{C}$

when you drive it onto a ferry boat to Alaska. What is their gauge pressure later, when their temperature has dropped to $–\text{40}\text{.}0\text{º}\text{C}$

?

1.62 atm

Convert an absolute pressure of $7\text{.}\text{00}\times {\text{10}}^5{\text{N/m}}^2$

to gauge pressure in ${\text{lb/in}}^2\text{.}$

(This value was stated to be just less than $\text{90}\text{.}{\text{0 lb/in}}^2$

in [link]. Is it?)

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 $\text{20}\text{.}0\text{º}\text{C}$

. (a) Find the gauge pressure inside such a bulb when it is hot, assuming its average temperature is $\text{60}\text{.}0\text{º}\text{C}$

(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?

(a) 0.136 atm

(b) 0.135 atm. The difference between this value and the value from part (a) is negligible.

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 of $\text{10}\text{.}0\text{º}\text{C}$

and rises to an altitude where its volume is twenty times the original volume and its temperature is $–\text{50}\text{.}0\text{º}\text{C}$

? (b) What is the gauge pressure? (Assume atmospheric pressure is constant.)

Confirm that the units of $\text{nRT}$

are those of energy for each value of $R$

(a) $8\text{.}\text{31}\text{J/mol}\cdot \text{K}$

, (b) $1\text{.}\text{99 cal/mol}\cdot \text{K}$

, and (c) $0\text{.}\text{0821 L}\cdot \text{atm/mol}\cdot \text{K}$

.

(a) $\text{nRT}=(\text{mol})(\text{J/mol}\cdot \text{K})(\text{K})=\text{J}$

(b) $\text{nRT}=(\text{mol})(\text{cal/mol}\cdot \text{K})(\text{K})=\text{cal}$

(c) $\begin{array}{lll}\text{nRT}& =& (\text{mol})(\text{L}\cdot \text{atm/mol}\cdot \text{K})(\text{K})\\ & =& \text{L}\cdot \text{atm}=({\text{m}}^3)({\text{N/m}}^2)\\ & =& \text{N}\cdot \text{m}=\text{J}\end{array}$

In the text, it was shown that $N/V=2\text{.}\text{68}\times {\text{10}}^{\text{25}}{\text{m}}^{-3}$

for gas at STP. (a) Show that this quantity is equivalent to $N/V=2\text{.}\text{68}\times {\text{10}}^{\text{19}}{\text{cm}}^{-3},$

as stated. (b) About how many atoms are there in one ${\text{μm}}^3$

(a cubic micrometer) at STP? (c) What does your answer to part (b) imply about the separation of atoms and molecules?

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 $\text{37}\text{.}0\text{º}\text{C}$

(body temperature).

An airplane passenger has $\text{100}{\text{cm}}^3$

of 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 $7\text{.}\text{50}\times {\text{10}}^4{\text{N/m}}^2?$

(a) What is the volume (in ${\text{km}}^3$

) 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.

(a) $6\text{.}\text{02}\times {\text{10}}^5{\text{km}}^3$

(b) $6\text{.}\text{02}\times {\text{10}}^8\text{km}$

An expensive vacuum system can achieve a pressure as low as $1\text{.}\text{00}\times {\text{10}}^{–7}{\text{N/m}}^2$

at $\text{20}\text{º}\text{C}$

. How many atoms are there in a cubic centimeter at this pressure and temperature?

The number density of gas atoms at a certain location in the space above our planet is about $1\text{.}\text{00}\times {\text{10}}^{\text{11}}{\text{m}}^{-3},$

and the pressure is $2\text{.}\text{75}\times {\text{10}}^{–\text{10}}{\text{N/m}}^2$

in this space. What is the temperature there?

A bicycle tire has a pressure of $7\text{.}\text{00}\times {\text{10}}^5{\text{N/m}}^2$

at a temperature of $\text{18}\text{.}0\text{º}\text{C}$

and contains 2.00 L of gas. What will its pressure be if you let out an amount of air that has a volume of $\text{100}{\text{cm}}^3$

at atmospheric pressure? Assume tire temperature and volume remain constant.

A high-pressure gas cylinder contains 50.0 L of toxic gas at a pressure of $1\text{.}\text{40}\times {\text{10}}^7{\text{N/m}}^2$

and a temperature of $\text{25}\text{.}0\text{º}\text{C}$

. Its valve leaks after the cylinder is dropped. The cylinder is cooled to dry ice temperature $(–\text{78}\text{.}5\text{º}\text{C})$

to 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?

(a) $9\text{.}\text{14}\times {\text{10}}^6{\text{N/m}}^2$

(b) $8\text{.}\text{23}\times {\text{10}}^6{\text{N/m}}^2$

(c) 2.16 K

(d) No. The final temperature needed is much too low to be easily achieved for a large object.

Find the number of moles in 2.00 L of gas at $\text{35}\text{.}0\text{º}\text{C}$

and under $7\text{.}\text{41}\times {\text{10}}^7{\text{N/m}}^2$

of pressure.

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.

41 km

(a) What is the gauge pressure in a $\text{25}\text{.}0\text{º}\text{C}$

car 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 and $\text{25}\text{.}0\text{º}\text{C}$

? Assume the temperature returns to $\text{25}\text{.}0\text{º}\text{C}$

and the volume remains constant.

(a) In the deep space between galaxies, the density of atoms is as low as ${\text{10}}^6{\text{atoms/m}}^3,$

and the temperature is a frigid 2.7 K. What is the pressure? (b) What volume (in ${\text{m}}^3$

) is occupied by 1 mol of gas? (c) If this volume is a cube, what is the length of its sides in kilometers?

(a) $3\text{.}7\times {\text{10}}^{-\text{17}}\text{Pa}$

(b) $6\text{.}0\times {\text{10}}^{\text{17}}{\text{m}}^3$

(c) $8\text{.}4\times {\text{10}}^2\text{km}$