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0r4 points| Previaus Answers Tipleri 19 P035 Mty Notes Ask Your An ideal diatomic gas follows...
can you help me with this plesae? O 3.5/7 points Previous Answers Tipler6 19 PO34 My Notes One mole of an ideal monatomic gas at an initial volume Vi30 L follows the cycle shown in the figure. All the processes are quasi-static. PkPa 200 Isotherm 100 2V, v.L (a) Find the temperature of each state of the cycle. X K (state 1) X K (state 2) X K (state 3) q (b) Find the heat flow for each part of...
10.0 L of an ideal diatomic gas at 1.00 atm and 200 K are contained in a cylinder with a piston. The gas first expands isobarically to 30.0 L (step 1). It then contracts adiabatically back to its original volume (step 2), and then cools isochorically back to its original pressure (step 3). a) Show the series of processes on a pV diagram. b) Calculate the temperature, pressure, and volume of the system at the end of each step in...
Calculate the change in entropy ΔS for 5.2 moles of an ideal gas when its thermodynamic state changes from p1 = 1.50 atm and T1 = 400.0 K to p2 = 3.00 atm and T2 = 600.0 K. The molar heat capacity of the gas at constant volume is CV,m = (7/2) R, and is independent of the temperature.
2 moles of compressed air (diatomic gas) in a cylinder under the initial condition T1=573K p1=500kPa. Found v1=0.019m^3 but can not remember then how to find V2. I think that it has something to do with T1=T2 condition then P2 can be found.... but stuck on how to proceed so with FULL written explanations with working would be much appreciated! All question info on practice exam below - note ISOTHERMAL EXPANSION. for part ii which after an explanation first. Two...
Determine the COP of the gas refrigeration system shown below. The system consists of two ideal compressors (C1 and C2 two ideal turbines (T1 and T21 and four heat exchangers (HX-1, HX-2, HX-3, and HX-4). Air is the gas of the refrigeration system. Heat is relected from air to the surroundings as it moves through HDX-1 and HX-2. Heat is accepted by air from the cooled spaces as it moves through HX-3 and HX-4. The temperatures and pressures at several...
A thermodynamic cycle ABC involving 2.5 mols of an ideal gas is shown below. (a) Find the absolute temperatures at points A, B, and C. (b) Find the work done by or on the system from A to B, from B to C, and from C to A (include the proper sign in each case). (c) Find the heat transferred to or from the system from A to B, from B to C, and from C to A (include the...
Ten. moles of ideal gas (monatomic), in the initial state P1=10atm, T1=300K are taken round the following cycle: a. A reversible isothermal expansion to V=246 liters, and b. A reversible adiabatic process to P=10 atm c. A reversible isobaric compression to V=24.6 liters Calculate the change of work (w), heat (q), internal energy (U), and entropy (S) of the system for each process?
Part A:Refer to diagram 2. A flask contains 85.2 moles of a monatomic ideal gas at pressure 6.9 atm and volume 13.4 liters (point A on the graph. Now, the gas undergoes a cycle of three steps: - First there is an isothermal expansion to pressure 3.65 atm (point B on the graph). - Next, there is an isochoric process in which the pressure is raised to P1 (point C on the graph). - Finally, there is an isobaric compression...
Thermodynamics Consider an insulated container of volume V2. N ideal gas molecules are initially confined within a sub-volume (V1) by a piston and the remaining volume V2 - Viis in vacuum. Let T., P., U1, S1, A1, H1, and G1 be the temperature, pressure, internal energy, entropy, Helmholtz free energy, enthalpy, and Gibbs free energy of the ideal gas at this state, respectively. Now, imagine that the piston is removed so that the gas has volume V2. After some time...
4. You are asked to perform thermodynamic analysis for a real gas that obeys the following equation of state: aP where "a" and "b" are constants (the numerical value of these constants is not important for this problem). You also know that the real gas has the following molar heat capacity, which you can assume depends only on the temperature: Cpm = A + BT with T in kelvin. Also, 2aPaP2 Note that, since the gas is real, the relationship...