CHEMISTRY:PRIN.+REACTIONS-OWLV2 ACCESS
8th Edition
ISBN: 9781305079298
Author: Masterton
Publisher: Cengage Learning
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Chapter 5, Problem 90QAP
Interpretation Introduction
Interpretation:
The distance at which the ring from the end at the ammonia was introduced needs to be determined.
Concept introduction:
Gas density is known as the ratio of mass of the gas and the volume occupied by that gas. The formula is as below:
Here, MM is the molar mass of the gas, V is the volume of gas, P is pressure of gas, T is temperature and R is the universal gas constant.
The kinetic model of gases is accounted for ideal gas behavior. The formula of average translational energy of gas is as below:
Here,
Et = average translational energy of gas
T = temperature in Kelvin
R = Universal gas constant
NA =
Effusion is known as the leakage of gas molecules from high to low pressure region via a pinhole. For any two gas molecules the formula to determine the time needed for effusion is as below:
Here, time1 and time2 is the time of effusion for gas1 and gas 2. MM1 and MM2 is the molar mass for gas1 and gas 2.
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A 5.00 L flask is evacuated and 44.81 g of solid dinitrogen tetroxide, N2O4, is introduced at −196 °C. The sample is then warmed to 25 °C during which time the N2O4 vaporizes and some of it dissociates to form brown NO2 gas. The pressure slowly increases until it stabilizes at 3.27 atm.
1. Write the balanced reaction for the dissociation of N2O4.
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A 5.00 L flask is evacuated and 44.81 g of solid dinitrogen tetroxide, N2O4, is introduced at −196 °C. The sample is then warmed to 25 °C during which time the N2O4 vaporizes and some of it dissociates to form brown NO2 gas. The pressure slowly increases until it stabilizes at 3.27 atm.
1. Write the balanced reaction for the dissociation of N2O4.
2. What would be the pressure in the flask at 25 °C if the gas were all N2O4?
3. What would be the pressure in the flask at 25 °C if all of the gas converted into NO2?
4. What are the mole fractions of N2O4 and NO2 once the pressure in the flask stabilizes at 3.27 atm?
If we could please work through Part 4, that would be great :)
A 2.00 L reaction container at 25.0 °C contains CO2 (g) and O2 (g). The total pressure of the gases in the container was 656 torr and the mole fraction of CO2 is 0.245.
A)Calculate the partial pressure of oxygen gas in the mixture.
B)Calculate the mass of oxygen gas in the mixture (in g).
C)Which gas will rise to the top of the container? Explain your answer.
Chapter 5 Solutions
CHEMISTRY:PRIN.+REACTIONS-OWLV2 ACCESS
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