Chemistry Gas Laws: Combined Gas Law: Videos & Practice Problems

The combined gas law is a fundamental principle in chemistry that illustrates the relationship between pressure, volume, and temperature of a gas. It is derived from three key gas laws: Boyle's law, Charles' law, and Gay-Lussac's law. Each of these laws describes how one variable affects another under specific conditions.

Boyle's law states that pressure (P) is inversely proportional to volume (V) when temperature is held constant, which can be expressed mathematically as:

\[ P \propto \frac{1}{V} \]

Charles' law indicates that volume is directly proportional to temperature (T) when pressure is constant, represented as:

\[ V \propto T \]

Gay-Lussac's law asserts that pressure is directly proportional to temperature when volume is constant, which can be written as:

\[ P \propto T \]

By combining these relationships, we arrive at the combined gas law, which can be expressed as:

\[ \frac{PV}{T} = k \]

Here, \( k \) is a constant that represents the specific conditions of the gas being studied.

Furthermore, when comparing two sets of conditions for a gas, the combined gas law can be rearranged to:

\[ \frac{P_1 V_1}{T_1} = \frac{P_2 V_2}{T_2} \]

This equation allows for the calculation of one variable when the others are known, making it a powerful tool in thermodynamics and gas behavior analysis.

In this scenario, we are analyzing the behavior of a gas sample as its volume and temperature change, while the number of moles remains constant. Initially, the gas has a volume of 900 milliliters (0.900 liters), a temperature of 520 Kelvin, and a pressure of 1.85 atmospheres. When the volume decreases to 330 milliliters (0.330 liters) and the temperature increases to 770 Kelvin, we need to determine the new pressure, denoted as \( P_2 \).

To solve this problem, we utilize the combined gas law, which is derived from the ideal gas law \( PV = nRT \). Since the number of moles (n) and the gas constant (R) remain unchanged, we can express the relationship between the initial and final states of the gas as:

\[ \frac{P_1 V_1}{T_1} = \frac{P_2 V_2}{T_2} \]

Here, \( P_1 \) is the initial pressure, \( V_1 \) is the initial volume, \( T_1 \) is the initial temperature, \( P_2 \) is the final pressure, \( V_2 \) is the final volume, and \( T_2 \) is the final temperature. Plugging in the known values:

\[ P_1 = 1.85 \, \text{atm}, \quad V_1 = 0.900 \, \text{L}, \quad T_1 = 520 \, \text{K} \]

\[ V_2 = 0.330 \, \text{L}, \quad T_2 = 770 \, \text{K} \]

We can rearrange the equation to isolate \( P_2 \):

\[ P_2 = \frac{P_1 V_1 T_2}{V_2 T_1} \]

Substituting the values into the equation gives:

\[ P_2 = \frac{(1.85 \, \text{atm}) \times (0.900 \, \text{L}) \times (770 \, \text{K})}{(0.330 \, \text{L}) \times (520 \, \text{K})} \]

After performing the calculations, we find that:

\[ P_2 \approx 7.47 \, \text{atm} \]

This result indicates that the pressure of the gas increases significantly due to the decrease in volume and the increase in temperature, demonstrating the principles of gas behavior as described by the combined gas law.