Consider n = 1.17 mols of an ideal gas on the pV diagram below where p1 = p2 = 3.15 x 10^5 Pa V1 = 5.64 x 10^–3 m^3 p3 = 9.89 x 10^5 Pa V2 = 3.58 x 10^–3 m^3 V3 = 1.14 x 10^–3 m^3 What is the temperature T1 of the ideal gas at point 1 on the pV diagram above? How much work is performed on the ideal gas as it is compressed isobarically (i.e. at constant pressure) from point 1 to point 2 on the pV diagram above? What is the temperature T2 of the ideal gas at point 2 on the pV diagram above? The ideal gas is then isothermally (i.e. at constant temperature) reduced to the point 3 shown on the pV diagram above. How much heat was added to the gas to do this?

Consider n = 1.17 mols of an ideal gas on the pV diagram below where p1 = p2 = 3.15 x 10^5 Pa V1 = 5.64 x 10^–3 m^3 p3 = 9.89 x 10^5 Pa V2 = 3.58 x 10^–3 m^3 V3 = 1.14 x 10^–3 m^3 What is the temperature T1 of the ideal gas at point 1 on the pV diagram above? How much work is performed on the ideal gas as it is compressed isobarically (i.e. at constant pressure) from point 1 to point 2 on the pV diagram above? What is the temperature T2 of the ideal gas at point 2 on the pV diagram above? The ideal gas is then isothermally (i.e. at constant temperature) reduced to the point 3 shown on the pV diagram above. How much heat was added to the gas to do this?

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Question

Consider n = 1.17 mols of an ideal gas on the pV diagram below where

p1 = p2 = 3.15 x 10^5 Pa V1 = 5.64 x 10^–3 m^3

p3 = 9.89 x 10^5 Pa V2 = 3.58 x 10^–3 m^3
V3 = 1.14 x 10^–3 m^3

What is the temperature T1 of the ideal gas at point 1 on the pV
diagram above?

How much work is performed on the ideal gas as it is compressed
isobarically (i.e. at constant pressure) from point 1 to point 2 on the pV diagram above?

What is the temperature T2 of the ideal gas at point 2 on the pV
diagram above?

The ideal gas is then isothermally (i.e. at constant temperature)
reduced to the point 3 shown on the pV diagram above. How much heat was added to the gas to do this?

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