Consider a system consisting of 3.0 mol CO2(g), initially at 35°C and 9.0 atm and confined to
a cylinder of cross-section 100.0 cm2. The sample is allowed to expand irreversibly and adiabatically against an external pressure of 2.5 atm until the piston has moved outwards through 25 cm. Assume that carbon dioxide may be considered a perfect gas with CV,m = 28.8
J K–1 mol–1, and calculate (a) q, (b) w, (c) ΔU, (d) ΔT, (e) ΔS.
Consider a system consisting of 3.0 mol CO2(g), initially at 35°C and 9.0 atm and confined...
[8] Consider a system consisting of 1.5 mol CO2(g), initially at 15oC and 9.0 atm and confined to a cylinder of cross-section 100.0 cm2. The sample is allowed to expand adiabatically against an external pressure of 1.5 atm until the piston has moved outwards through 15 cm. Assume that carbon dioxide may be considered a perfect gas with Cv.m-288] K-1 mol-1, and calculate (a) q, (b) w, (c) Δυ, (d) ΔΤ, (e) as
how to do this? thank u? Consider a system consisting of 1.0 mol CO_2 (assumed to be a perfect gas) at 15 degreeC confined to a cylinder of cross-section 10 cm^2 at 10 atm. The gas is diowed to expand adiabatic ally and irreversibly against a constant pressure of 1.0 atm. Calculate when piston has moved 20 cm.
Five moles of carbon dioxide (CO2), initially 3 atm and 300 K, is trapped inside a piston-cylinder assembly. It is then allowed to expand against atmospheric pressure adiabatically. The constant- pressure heat capacity of CO2 is given by the following equation: p = 5.4574 (1.045 × 10-3)(T/K)-(1.157 × 105)(T/K)-2 (a) If we assume that the expansion is infinitely slow and quasi-static, calculate the final temperature and total volume of the carbon dioxide gas when it reaches 1 atm. Also calculate...