For an ideal gas expanding according to Boyle's Law, integrate the expressions (a) J pdv and (b) - J vdp (c) Sketch the process on the pV plane and shade the areas which represent these integrals.
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- Calculate ΔA for the isothermal compression of 1.54 mol of an ideal gas at 322 K from an initial volume of 51.2 L to a final volume of 13.1 L Does it matter whether the path is reversible or irreversible?.The potential function between molecules of a simple non-polar gas, when the mass centres are separated by a distance r, is given by the well-known expressions: p(r) = 4€[(÷) '? – (#)*] For this gas in question: e/k = 120K and b, = No =0.063 m³/kmol a) What is the magnitude of the potential o(r) at its minimum?Part A: 10 moles of ideal gas initially at 10 atm and 250 K is expanded isothermally and reversibly to a final pressure of 2 atm. Calculate W, AU, and Q in Joules. Part B: The same gas in problem A, starting in the same initial state, is expanded isothermally against a constant external pressure of 2 atm, to a final pressure of 2 atm. Calculate W, AU, and Q in Joules for this irreversible process. Part C: The same gas in part B, starting in the same initial state, is expanded isothermally to a final pressure of 2 atm. The process is carried out in 4 stages. First the gas is expanded against a constant pressure of 8 atm, to 8 atm. Then the gas is expanded against a constant pressure of 6 atm, to 6 atm. Then the gas is expanded against a constant pressure of 4 atm, to 4 atm. Finally, the gas is expanded against a constant pressure of 2 atm, to 2 atm. Calculate W, AU, and Q in Joules for the 4-step process.
- A balloon holding 4.50 moles of oxygen (0,) gas absorbs 935 J of thermal energy while doing 112 J of work expanding to a larger volume. HINT (a) Apply the first law of thermodynamics. (b) Recall that the molar specific heat at constant volume, C, takes different values depending on whether the gas is monatomic or diatomic. Click the hint button again to remove this hint. (a) Find the change in the balloon's internal energy (in J). (b) Calculate the change in temperature of the gas (in K). KPlease asapAn ideal gas initially at P₁, V₁, and T₁ is taken through a cycle as shown below. (Let the factor n = 3.9. Note, this is the factor by which volume and pressure increase, as noted on the PV-diagram; it is NOT the number of moles of gas.) P nP; P₁ B D nv; (a) Find the net work done on the gas per cycle for 1.35 mol of gas initially at 0°C. kJ (b) What is the net energy added by heat to the system per cycle? kJ
- How to solve this question1.00 mol of an ideal gas at 49 K is expanded isothermally from an initial pressure of 3.00 atm to a final pressure of 1.00 atm in two ways: (a) reversibly, (b) against a constant external pressure of 1.00 atm. Determine the values of g, w delta U, delta H, delta S, delta Ssr ("sur” surroundings), and AStot for each path.Repeat the preceding calculations for an ideal diatomic gas expanding adiabatically from an initial volume of 0.500 m3 to a final volume of 1.25 m3, starting at a pressure of 1.01 105 Pa. (You must sketch the curve to find the work.) P2 = W ≈