For each exercise, you can simulate the described conditions by changing the values in the Run...

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For each exercise, you can simulate the described conditions by changing the values in the Run Experiment tool of the Simulation. To be able to measure the effects on pressure or volume, slide the Rspd bar in the Properties box to either P (atm) or V (L), respectively. The slider bar for either pressure or volume will turn yellow when it is selected, and it becomes the only dependent variable, i.e. the value you measure in response to changing the other properties. Note that when either pressure or volume is selected with Rspd, the respective value can no longer be directly controlled. Let us first examine the behavior of an ideal gas when we force the volume to be a value of our choosing. We can examine how changes to the absolute temperature and number of moles affects the pressure of the gas particles (by selecting pressure with Rspd such that pressure cannot be controlled). There are 0.05 mol of argon at a temperature of 275.00 K occupying a volume of 3.50 L. Use the Run Experiment tool in the Simulation to determine the initial pressure of the gas and the new pressure values when the temperature or number of moles is changed to complete the following statements. Match the words in the left column to the appropriate blanks in the sentences on the right. Make certain each sentence is complete before submitting your answer. View Available Hint(s) Reset Help decreases The initial pressure of the argon gas is 0.75 atm From the initial conditions (0.05 mol and 275.00 K), if you increased the amount of argon to 0.09 mol, the new pressure would be 0.35 atm Therefore, pressure with the 0.58 atm number of moles in proportion. direct From the initial conditions (0.05 mol and 275.00 K), if you increased the temperature by 80.00 K. the new pressure would be Therefore, pressure with 0.32 atm temperature in proportion, inverse 0.46 atm 0.42 atm increases 0.65 atm For this exercise, you can simulate the described conditions by changing the values in the Run Experiment tool of the Simulation. To be able to measure the effects on the gas volume, slide the Rspd bar in the Properties box to V (L) so that the volume bar turns yellow. This way. volume becomes the only dependent variable. Note that when volume is selected with Rspd, its value can no longer be directly controlled. Suppose a piston automatically adjusts to maintain a gas at a constant pressure of 10.40 atm. For the initial conditions, there are 0.02 mol of hellum at a temperature of 225.00 K. This gas occupies a volume of 0.04 L under those conditions. What volume will the gas occupy if the number of moles s increased to 0.05 mol (n₂) from the initial conditions? What volume will the gas occupy if the temperature is increased to 325.00 K (7₂) from the initial conditions? Express the volumes in liters to two decimal places separated by a comma. For each exercise, you can simulate the described conditions by changing the values in the Run Experiment tool of the Simulation. To be able to measure the effects on pressure or volume, slide the Rspd bar in the Properties box to either P (atm) or V (L), respectively. The slider bar for either pressure or volume will turn yellow when it is selected, and it becomes the only dependent variable, i.e. the value you measure in response to changing the other properties. Note that when either pressure or volume is selected with Rspd, the respective value can no longer be directly controlled. Let us first examine the behavior of an ideal gas when we force the volume to be a value of our choosing. We can examine how changes to the absolute temperature and number of moles affects the pressure of the gas particles (by selecting pressure with Rspd such that pressure cannot be controlled). There are 0.05 mol of argon at a temperature of 275.00 K occupying a volume of 3.50 L. Use the Run Experiment tool in the Simulation to determine the initial pressure of the gas and the new pressure values when the temperature or number of moles is changed to complete the following statements. Match the words in the left column to the appropriate blanks in the sentences on the right. Make certain each sentence is complete before submitting your answer. View Available Hint(s) Reset Help decreases The initial pressure of the argon gas is 0.75 atm From the initial conditions (0.05 mol and 275.00 K), if you increased the amount of argon to 0.09 mol, the new pressure would be 0.35 atm Therefore, pressure with the 0.58 atm number of moles in proportion. direct From the initial conditions (0.05 mol and 275.00 K), if you increased the temperature by 80.00 K. the new pressure would be Therefore, pressure with 0.32 atm temperature in proportion, inverse 0.46 atm 0.42 atm increases 0.65 atm For this exercise, you can simulate the described conditions by changing the values in the Run Experiment tool of the Simulation. To be able to measure the effects on the gas volume, slide the Rspd bar in the Properties box to V (L) so that the volume bar turns yellow. This way. volume becomes the only dependent variable. Note that when volume is selected with Rspd, its value can no longer be directly controlled. Suppose a piston automatically adjusts to maintain a gas at a constant pressure of 10.40 atm. For the initial conditions, there are 0.02 mol of hellum at a temperature of 225.00 K. This gas occupies a volume of 0.04 L under those conditions. What volume will the gas occupy if the number of moles s increased to 0.05 mol (n₂) from the initial conditions? What volume will the gas occupy if the temperature is increased to 325.00 K (7₂) from the initial conditions? Express the volumes in liters to two decimal places separated by a comma.

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Consider the ideal gas equation as follows PV nRT Px35005x00821275 P 032 a... View the full answer