An ideal diatomic gas has an initial pressure of 1.00×10°P , an initial volume of 2.00m', and an initial temperature of 300K. (This is point 1 on the pV-diagram.) The gas has an isochoric increase in pressure to 2.00x10°Pa. (This is point 2 on the pV-diagram.) The gas then has an isothermal expansion to a volume of 3.00m'. (This is point 3 on the pV-diagram.) The pressure is then reduced adiabatically back down to its original pressure of 1.00×10°P . (This is point 4 on the pV-diagram.) Finally, the gas has an isobaric decrease in volume to its original volume of 2.00m'. (The gas is back to point 1 on the pV-diagram.) a. Fill in the missing values on the following table. Point Volume, Pressure, Temperature, v (m³) p(10ʻPa) T(K) 1 2.00 1.00 300 2 2.00 3 3.00 4 1.00
An ideal diatomic gas has an initial pressure of 1.00×10°P , an initial volume of 2.00m', and an initial temperature of 300K. (This is point 1 on the pV-diagram.) The gas has an isochoric increase in pressure to 2.00x10°Pa. (This is point 2 on the pV-diagram.) The gas then has an isothermal expansion to a volume of 3.00m'. (This is point 3 on the pV-diagram.) The pressure is then reduced adiabatically back down to its original pressure of 1.00×10°P . (This is point 4 on the pV-diagram.) Finally, the gas has an isobaric decrease in volume to its original volume of 2.00m'. (The gas is back to point 1 on the pV-diagram.) a. Fill in the missing values on the following table. Point Volume, Pressure, Temperature, v (m³) p(10ʻPa) T(K) 1 2.00 1.00 300 2 2.00 3 3.00 4 1.00
Chapter2: The Kinetic Theory Of Gases
Section: Chapter Questions
Problem 81AP: One process for decaffeinating coffee uses carbon dioxide ( M=44.0 g/mol) at a molar density of...
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