According to the ideal gas law, a 0.9988 mol sample of xenon gas in a 1.401 L container at 267.4 K should exert a pressure of 15.64 atm. What is the percent difference between the pressure calculated using the van der Waals' equation and the ideal pressure? For Xe gas, a = 4.194 L2atm/mol2 and b = 5.105×10-2 L/mol.
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According to the ideal gas law, a 0.9988 mol sample of xenon gas in a 1.401...
According to the ideal gas law, a 10.01 mol sample of xenon gas in a 0.8137 L container at 500.4 K should exert a pressure if 505.1 atm. What is the percent difference between the pressure calculated using the van der Waals' equation and the ideal pressure? For Xe gas, a = 4.194 L^2atm/mol^2 and b = 5.105 x 10^-2 L/mol.
According to the ideal gas law, a 0.9249 mol sample of xenon gas in a 1.135 L container at 269.1 K should exert a pressure of 17.99 atm. By what percent does the pressure calculated using the van der Waals' equation differ from the ideal pressure? For Xe gas, a = 4.194 L^2atm/mol^2 and b = 5.105 times 10^-2 L/mol. %
A 9.262 mol sample of xenon gas is maintained in a 0.8496 L container at 299.3 K. What is the pressure in atm calculated using the van der Waals' equation for Xe gas under these conditions? For Xe, a = 4.194 L2atm/mol2 and b = 5.105×10-2 L/mol.
According to the ideal gas law, a 0.9054 mol sample of krypton gas in a 1.023 L container at 274.0 K should exert a pressure of 19.90 atm. What is the percent difference between the pressure calculated using the van der Waals' equation and the ideal pressure? For Kr gas, a = 2.318 L2atm/mol2 and b = 3.978×10-2 L/mol. % According to the ideal gas law, a 9.344 mol sample of oxygen gas in a 0.8267 L container at 500.1...
According to the ideal gas law, a 1.001 mol sample of argon gas in a 1.589 L container at 270.1 K should exert a pressure of 13.96 atm. What is the percent difference between the pressure calculated using the van der Waals' equation and the ideal pressure? For Ar gas, a = 1.345 L2atm/mol2 and b = 3.219×10-2 L/mol.
According to the ideal gas law, a 1.099 mol sample of nitrogen gas in a 1.520 L container at 271.3 K should exert a pressure of 16.10 atm. What is the percent difference between the pressure calculated using the van der Waals' equation and the ideal pressure? For N2 gas, a = 1.390 L2atm/mol2 and b = 3.910×10-2 L/mol.
According to the ideal gas law, a 10.74 mol sample of krypton gas in a 0.8444 L container at 498.7 K should exert a pressure of 520.5 atm. What is the percent difference between the pressure calculated using the van der Waals' equation and the ideal pressure? For Kr gas, a = 2.318 L2atm/mol2 and b = 3.978×10-2 L/mol. ____%
According to the ideal gas law, a 1.066 mol sample of krypton gas in a 1.927 L container at 272.4 K should exert a pressure of 12.37 atm. By what percent does the pressure calculated using the van der Waals' equation differ from the ideal pressure? For Kr gas, a = 2.318 L2atm/mol2 and b = 3.978×10-2 L/mol. ___% Hint: % difference = 100×(P ideal - Pvan der Waals) / P ideal
(chp.13) According to the ideal gas law, a 1.010 mol sample of krypton gas in a 1.123 L container at 269.7 K should exert a pressure of 19.90 atm. What is the percent difference between the pressure calculated using the van der Waals' equation and the ideal pressure? For Kr gas, a = 2.318 L2atm/mol2 and b = 3.978×10-2 L/mol. %
According to the ideal gas law, a 0.9530 mol sample of methane gas in a 1.223 L container at 267.0 K should exert a pressure of 17.07 atm. By what percent does the pressure calculated using the van der Waals' equation differ from the ideal pressure? For CH4 gas, a = 2.253 L2atm/mol2 and b = 4.278×10-2 L/mol. ___ %