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Chapter 18: Problem 4

A \(3.00-\mathrm{L}\) tank contains air at 3.00 \(\mathrm{atm}\) and \(20.0^{\circ} \mathrm{C} .\) The tank is sealed and cooled until the pressure is 1.00 atm. (a) What is the temperature then in degrees Celsius? Assume the volume of the tank is constant. (b) If the temperature is kept at the value found in part (a) and the gas is compressed, what is the vohme when the pressure again becomes 3.00 \(\mathrm{atm} ?\)

Short Answer

Expert verified
The final temperature is -175.43°C and the volume at 3.00 atm is 1.00 L.

Step by step solution

01

Understanding the Problem

We have a tank at an initial pressure of 3.00 atm and a temperature of 20°C. It is then sealed and cooled until the pressure drops to 1.00 atm. We are asked to find the final temperature in degrees Celsius. Then, while maintaining that temperature, we compress the gas back to 3.00 atm and need to find the new volume.
02

Convert Initial Temperature to Kelvin

Since gas laws require temperature in Kelvin, convert the initial Celsius temperature to Kelvin. The formula is \[T(K) = T(°C) + 273.15\]. So, the initial temperature is \[T_1 = 20.0 + 273.15 = 293.15 \mathrm{K}\].
03

Apply Gay-Lussac's Law for Temperature and Pressure

Gay-Lussac's Law relates pressure and temperature for a given volume: \(\frac{P_1}{T_1} = \frac{P_2}{T_2}\). Given \(P_1 = 3.00 \, \mathrm{atm}\), \(T_1 = 293.15 \, \mathrm{K}\), and \(P_2 = 1.00 \, \mathrm{atm}\), solve for \(T_2\).
04

Calculate Final Temperature in Kelvin

Rearrange \(\frac{P_1}{T_1} = \frac{P_2}{T_2}\) to find \(T_2 = \frac{P_2 \times T_1}{P_1}\). Substituting, \(T_2 = \frac{1.00 \, \mathrm{atm} \times 293.15 \, \mathrm{K}}{3.00 \, \mathrm{atm}} = 97.72 \, \mathrm{K}\).
05

Convert Final Temperature to Celsius

Convert the final temperature back to degrees Celsius: \[T(°C) = T(K) - 273.15\]. Thus, \[T_2(°C) = 97.72 - 273.15 = -175.43^{\circ}\mathrm{C}\].
06

Apply Boyle's Law for Pressure and Volume

With constant temperature, Boyle's Law applies: \(P_1V_1 = P_2V_2\). We have \(P_2 = 1.00 \, \mathrm{atm}\), but we need to find \(V_2\) when \(P_3 = 3.00 \, \mathrm{atm}\). Rearrange to find \(V_2 = \frac{P_2V_1}{P_3}\).
07

Calculate New Volume at 3.00 atm

Substituting into the equation from the previous step, \(V_2 = \frac{1.00 \, \mathrm{atm} \times 3.00 \, \mathrm{L}}{3.00 \, \mathrm{atm}} = 1.00 \, \mathrm{L}\).

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Key Concepts

These are the key concepts you need to understand to accurately answer the question.

Gas Laws
Gas laws are a set of laws in thermodynamics that describe how gases behave under different conditions of pressure, volume, and temperature. These laws are essential for understanding how gases interact in controlled environments like a tank or container. The three main gas laws we often refer to are Boyle's Law, Charles's Law, and Gay-Lussac's Law, each dealing with a different variable relationship while keeping one variable constant.
Understanding these laws helps us predict how changes in one aspect of a gas's condition can affect another, making them incredibly useful in fields ranging from chemistry to engineering. In the case of our problem, Gay-Lussac's Law and Boyle's Law play crucial roles in understanding the behavior of the gas inside the tank.
Gay-Lussac's Law
Gay-Lussac's Law describes the relationship between pressure and temperature of a gas at constant volume. It states that the pressure of a gas is directly proportional to its absolute temperature, provided the volume remains unchanged. Mathematically, this relation is expressed as \(\frac{P_1}{T_1} = \frac{P_2}{T_2}\).
In the original exercise, we use Gay-Lussac's Law to determine how the pressure decrease in a tank, from 3.00 atm to 1.00 atm, results in a change in temperature, assuming the volume does not change. By applying this law, we find the new temperature when the pressure is different, helping us understand the cooling process in the tank.
Boyle's Law
Boyle's Law explains the inverse relationship between the pressure and volume of a gas at constant temperature. This means that when the pressure of a gas increases, its volume decreases proportionally, as long as the temperature remains the same. The mathematical expression for this relationship is \(P_1V_1 = P_2V_2\).
In our exercise, Boyle's Law helps us understand what happens when we compress the gas in the tank back to the original pressure of 3.00 atm, after cooling it. Since the temperature is kept constant at this point, we can calculate the new reduced volume owing to the pressure change, using the formula to find that the volume decreases to 1.00 L.
Pressure-Volume Relationship
The pressure-volume relationship is central to the gas laws, particularly Boyle's Law. It describes how the volume of a gas changes in response to changes in pressure when temperature is held steady. This relationship is vital for predicting how gases behave under compression.
In practical terms, understanding this relationship allows scientists and engineers to design equipment and processes that can safely and efficiently handle gases under varying pressures. In the exercise, this concept helped to find out the new volume of gas when the pressure was returned to its initial state, demonstrating the interplay between these two key variables. This understanding is crucial for applications involving gas storage and transfer.

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Most popular questions from this chapter

(a) Calculate the specific heat capacity at constant volume of water vapor, assuming the nonlinear triatomic molecule has three translational and three rotational degrees of freedom and that vibrational motion does not contribute. The molar mass of water is 18.0 g/mol. (b) The actual specific heat capacity of water vapor at low pressures is about 2000 \(\mathrm{J} / \mathrm{kg} \cdot \mathrm{K}\) . Compare this with your calculation and comment on the actual role of vibrational motion.

(a) Oxygen \(\left(\mathrm{O}_{2}\right)\) has a molar mass of 32.0 \(\mathrm{g} / \mathrm{mol}\) . What is the average translational kinetic energy of an oxygen molecule at a temperature of 300 \(\mathrm{K} ?\) (b) What is the average value of the square at a of its speed? (c) What is the root-mean-square speed? (d) What is the momentum of an oxygen molecule traveling at this speed? (e) Suppose an oxygen molecule traveling at this speed bounces back and forth between opposite sides of a cubical vessel 0.10 \(\mathrm{m}\) on a side. What is the average force the molecule exerts on one of the walls of the container? (Assume that the molecule's velocity is perpendicular to the two sides that it strikes.) (f) What is the aver- age force per unit area? (g) How many oxygen molecules traveling at this speed are necessary to produce an average pressure of 1 \(\mathrm{atm} ?\) (h) Compute the number of oxygen molecules that are actually contained in a vessel of this size at 300 \(\mathrm{K}\) and atmospheric pressure. (i) Your answer for part (h) should be three times as large as the answer for part (g). Where does this discrepancy arise?

The speed of propagation of a sound wave in air at \(27^{\circ} \mathrm{C}\) is about 350 \(\mathrm{m} / \mathrm{s}\) . Calculate, for comparison, (a) \(v_{\mathrm{ms}}\) for nitrogen molecules and (b) the rms value of \(v_{x}\) at this temperature. The molar mass of nitrogen \(\left(\mathrm{N}_{2}\right)\) is \(28.0 \mathrm{g} / \mathrm{mol} .\)

It is possible to make crystalline solids that are only one layer of atoms thick. Such "two-dimensional" crystals can be created by depositing atoms on a very flat surface. (a) If the atoms in such a two-dimensional crystal can move only within the plane of the crystal, what will be its molar heat capacity near room temperature? Give your answer as a multiple of \(R\) and in \(\mathrm{J} / \mathrm{nol} \cdot \mathrm{K}\) . (b) At very low temperatures, will the molar heat capacity of a two- dimensional crystal be greater than, less than, or equal to the result you found in part (a)? Explain why.

Helium gas with a volume of 2.60 \(\mathrm{L}\) , under a pressure of 1.30 atm and at a temperanure of \(41.0^{\circ} \mathrm{C},\) is warmed until both pressure and volume are doubled. (a) What is the final temperature? (b) How many grams of helium are there? The molar mass of helium is 4.00 \(\mathrm{g} / \mathrm{mol.}\)
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