If 2.05 mol of an ideal gas is at 449.3 kPa and 433 K, what is the volume of the gas?
Find the volume of 2.50 mol of an ideal gas at 26.0 °C and a pressure of 413 kPa Use the ideal gas law and R = 0.0821 atm l/mol k.
A 0.450-mol sample of an ideal diatomic gas at 372 kPa and 312 K expands quasi-statically until the pressure decreases to 147 kPa. Find the final temperature and volume of the gas, the work done by the gas, and the heat absorbed by the gas if the expansion is the following. (a) Isothermal final temperature _______ volume of the gas _______ work done by the gas _______ heat absorbed _______ (b) adiabatic final temperature _______ volume of the gas _______ work done by the gas _______ heat absorbed _______
The volume of 3.3 mol of ideal gas is 45.7 L at 350 K. Calculate its pressure (in atmospheres). L atm L kPa • Use R = 0.08206 314 for the ideal gas constant. mol K Your answer should have two significant figures. Do NOT include units in your response. mol K for the Provide your answer below:
If 75.5 mol of an ideal gas is at 3.55 atm and 403 K, what is the volume of the gas? volume:
If 34.5 mol of an ideal gas is at 5.25 atm and 393 K, what is the volume of the gas? volume: L
If 75.5 mol of an ideal gas is at 3.55 atm and 403 K, what is the volume of the gas? volume: L
If 35.5 mol of an ideal gas is at 2.47 atm and 465 K, what is the volume of the gas?
If 80.5 mol of an ideal gas is at 5.79 atm and 387 K, what is the volume of the gas?
Find the volume of 4.50 mol of an ideal gas at 25.0°C and a pressure of 419 kPa. Use the ideal gas law and R = 0.0821 atm • L/mol • K.
A container holds 4.5 mol of an ideal monatomic gas with a pressure of 125 kPa. The container initially has a volume of 0.10 m3. The gas undergoes an adiabatic expansion until it reaches a volume of 0.3 m3 and a pressure of 20.0 kPa. What is the thermal energy of the gas after the expansion? How much energy went into or out of the gas as work during the expansion? (Positive for energy into the gas, negative for energy...