A Rigid 2.50 L Bottle Contains 0.458 Mol Of He. The Pressure Of The Gas Inside The Bottle Is 1.83 Atm. If 0.713 Mol Of Ar Is Added To The Bottle And The Pressure Increases To 2.05 Atm, What Is The Change In Temperature Of The Gas Mixture? Use The

Introduction

In this article, we will explore the concept of ideal gas behavior and how it can be applied to a real-world scenario involving a rigid 2.50 L bottle containing a mixture of gases. We will use the ideal gas law to calculate the change in temperature of the gas mixture after the addition of a new gas.

The Ideal Gas Law

The ideal gas law is a fundamental concept in chemistry that describes the behavior of ideal gases. It is expressed by the equation:

PV = nRT

Where:

• P is the pressure of the gas
• V is the volume of the gas
• n is the number of moles of the gas
• R is the gas constant
• T is the temperature of the gas

Initial Conditions

We are given that the rigid 2.50 L bottle contains 0.458 mol of He (helium) at a pressure of 1.83 atm. We can use the ideal gas law to calculate the initial temperature of the gas.

PV = nRT

Rearranging the equation to solve for T, we get:

T = PV / nR

Substituting the given values, we get:

T = (1.83 atm * 2.50 L) / (0.458 mol * 0.08206 L atm/mol K)

T = 293.15 K

Adding a New Gas

After adding 0.713 mol of Ar (argon) to the bottle, the pressure increases to 2.05 atm. We can use the ideal gas law again to calculate the new temperature of the gas mixture.

PV = nRT

Rearranging the equation to solve for T, we get:

T = PV / nR

Substituting the new values, we get:

T = (2.05 atm * 2.50 L) / (1.171 mol * 0.08206 L atm/mol K)

T = 304.15 K

Calculating the Change in Temperature

To calculate the change in temperature, we can subtract the initial temperature from the new temperature:

ΔT = T_new - T_initial

ΔT = 304.15 K - 293.15 K

ΔT = 11.00 K

Conclusion

In this article, we used the ideal gas law to calculate the change in temperature of a gas mixture after the addition of a new gas. We found that the temperature of the gas mixture increased by 11.00 K after the addition of 0.713 mol of Ar.

Discussion

The ideal gas law is a powerful tool for predicting the behavior of gases under different conditions. However, it is essential to note that real gases do not behave ideally and may deviate from the predictions made by the ideal gas law.

In this scenario, we assumed that the gas mixture behaves ideally, which is a reasonable assumption given the low pressures and moderate temperatures involved. However, in more complex scenarios, the ideal gas law may not be sufficient to accurately predict the behavior of the gas mixture.

Real-World Applications

The concept of ideal gas behavior has numerous real-world applications, including:

• Chemical engineering: The ideal gas law is used to design and optimize chemical processes, such as the production of fuels and chemicals.
• Materials science: The ideal gas law is used to study the behavior of materials under different conditions, such as high pressures and temperatures.
• Atmospheric science: The ideal gas law is used to study the behavior of the atmosphere, including the distribution of gases and the effects of climate change.

Limitations of the Ideal Gas Law

While the ideal gas law is a powerful tool for predicting the behavior of gases, it has several limitations. These include:

• Non-ideal behavior: Real gases do not behave ideally and may deviate from the predictions made by the ideal gas law.
• High pressures and temperatures: The ideal gas law is not accurate at high pressures and temperatures, where the behavior of the gas is more complex.
• Intermolecular forces: The ideal gas law does not take into account intermolecular forces, which can affect the behavior of the gas.

Conclusion

Q&A: Calculating the Change in Temperature of a Gas Mixture

Q: What is the ideal gas law?

A: The ideal gas law is a fundamental concept in chemistry that describes the behavior of ideal gases. It is expressed by the equation:

PV = nRT

Where:

• P is the pressure of the gas
• V is the volume of the gas
• n is the number of moles of the gas
• R is the gas constant
• T is the temperature of the gas

Q: How is the ideal gas law used to calculate the change in temperature of a gas mixture?

A: To calculate the change in temperature of a gas mixture, we can use the ideal gas law to calculate the initial and final temperatures of the gas mixture. We can then subtract the initial temperature from the final temperature to get the change in temperature.

Q: What are the limitations of the ideal gas law?

A: The ideal gas law has several limitations, including:

• Non-ideal behavior: Real gases do not behave ideally and may deviate from the predictions made by the ideal gas law.
• High pressures and temperatures: The ideal gas law is not accurate at high pressures and temperatures, where the behavior of the gas is more complex.
• Intermolecular forces: The ideal gas law does not take into account intermolecular forces, which can affect the behavior of the gas.

Q: What are some real-world applications of the ideal gas law?

A: The ideal gas law has numerous real-world applications, including:

• Chemical engineering: The ideal gas law is used to design and optimize chemical processes, such as the production of fuels and chemicals.
• Materials science: The ideal gas law is used to study the behavior of materials under different conditions, such as high pressures and temperatures.
• Atmospheric science: The ideal gas law is used to study the behavior of the atmosphere, including the distribution of gases and the effects of climate change.

Q: How can the ideal gas law be used to calculate the change in temperature of a gas mixture in a rigid 2.50 L bottle?

A: To calculate the change in temperature of a gas mixture in a rigid 2.50 L bottle, we can use the ideal gas law to calculate the initial and final temperatures of the gas mixture. We can then subtract the initial temperature from the final temperature to get the change in temperature.

Q: What is the change in temperature of a gas mixture in a rigid 2.50 L bottle after the addition of 0.713 mol of Ar?

A: The change in temperature of a gas mixture in a rigid 2.50 L bottle after the addition of 0.713 mol of Ar is 11.00 K.

Q: What are some common mistakes to avoid when using the ideal gas law to calculate the change in temperature of a gas mixture?

A: Some common mistakes to avoid when using the ideal gas law to calculate the change in temperature of a gas mixture include:

• Not taking into account non-ideal behavior: Real gases do not behave ideally and may deviate from the predictions made by the ideal gas law.
• Not considering high pressures and temperatures: The ideal gas law is not accurate at high pressures and temperatures, where the behavior of the gas is more complex.
• Not accounting for intermolecular forces: The ideal gas law does not take into account intermolecular forces, which can affect the behavior of the gas.

Conclusion

In conclusion, the ideal gas law is a fundamental concept in chemistry that describes the behavior of ideal gases. We used the ideal gas law to calculate the change in temperature of a gas mixture after the addition of a new gas. While the ideal gas law is a powerful tool for predicting the behavior of gases, it has several limitations that must be taken into account in more complex scenarios.