An ideal gas of 79.767moles is taken through the following cycle: 1. Expansion at constant pressure of 1.353atm from 1.37m³ to 2.69m³ 2. Cooling at constant volume to a pressure of 0.131atm 3. Compression at constant pressure to a final volume of 1.37m³ 4. Heating at constant volume to a final pressure of 1.353atm Determine the magnitude of the temperature difference between the points where the pressure and volume are 1.353atm, 1.37m³ and the point where the pressure and volume are 0.131atm, 2.69 m³ (in °C)

An ideal gas of 79.767moles is taken through the following cycle: 1. Expansion at constant pressure of 1.353atm from 1.37m³ to 2.69m³ 2. Cooling at constant volume to a pressure of 0.131atm 3. Compression at constant pressure to a final volume of 1.37m³ 4. Heating at constant volume to a final pressure of 1.353atm Determine the magnitude of the temperature difference between the points where the pressure and volume are 1.353atm, 1.37m³ and the point where the pressure and volume are 0.131atm, 2.69 m³ (in °C)

Physics for Scientists and Engineers, Technology Update (No access codes included)

9th Edition

ISBN:9781305116399

Author:Raymond A. Serway, John W. Jewett

Publisher:Raymond A. Serway, John W. Jewett

Chapter21: The Kinetic Theory Of Gases

Section: Chapter Questions

Problem 21.4P: In an ultrahigh vacuum system (with typical pressures lower than 10-7 pascal), the pressure is...

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