2. A gas at 300 K and 1 bar (state 1) flows through an adiabatic compressor and exits at 20bar and 700 K (state 2). The gas obeys the following equation of state, where a and B areconstants.v-BThe values are given as a = 10-3 _m³kbar molthe gas at 1 bar is Cp = 30mol KRT ар+P Tand B = 8 x 10-5 m³. The heat capacity ofmol Prove the following relation. [kl]dsсо€ (P) P + * (7),dP=TP1dv

Answered: Image /qna-images/answer/2d616f2f-1662-488b-b3f8-7091c2eae6fb.jpg

2. A gas at 300 K and 1 bar (state 1) flows through an adiabatic compressor and exits at 20 bar and 700 K (state 2). The gas obeys the following equation of state, where a and B are constants. RT ар v-B = P + T Р The values are given as a = 10-3_m³K bar mol the gas at 1 bar is Cp = 30- mol K and B = 8 x 10-5 m³. The heat capacity of mol

2. A gas at 300 K and 1 bar (state 1) flows through an adiabatic compressor and exits at 20 bar and 700 K (state 2). The gas obeys the following equation of state, where a and B are constants. RT ар v-B = P + T Р The values are given as a = 10-3_m³K bar mol the gas at 1 bar is Cp = 30- mol K and B = 8 x 10-5 m³. The heat capacity of mol

Physical Chemistry

2nd Edition

ISBN:9781133958437

Author:Ball, David W. (david Warren), BAER, Tomas

Publisher:Ball, David W. (david Warren), BAER, Tomas

Chapter2: The First Law Of Thermodynamics

Section: Chapter Questions

Problem 2.32E: Many compressed gases come in large,heavy metal cylindersthat are so heavy that they need a special...

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Two ideal gases, one monoatomic and the other diatomic are mixed with one another and form an ideal gas again. The equation of the adiabatic process of the mixture is 11 PVY= = constant; where What is the ratio of the number of molecules of the monoatomic gas to that of the diatomic gas in the mixture?
1 mol monoatomic ideal gas experienced an irreversible adiabatic process from state (P₁, T₁) to a final state (1atm, 273 K). AS is determined to be 20.9 J K-¹ mol-¹, and w=-1255J, C₁ = 3R/2, S (273K)= 188.3JK¯¹ mol-¹. Evaluate AU, AG of the process as well as the m initial state (P₁, T₁).
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