Assuming that CO2 is an ideal gas, calculate ∆H° and ∆S° for the following process: CO2(g,...

C60(s) + 60 O2(g) --> 60 CO2(g) The change in internal energy in the following combustion...

C60(s) + 60 O2(g) --> 60 CO2(g) The change in internal energy in the following combustion reaction of C60(s) is -25968 kJ/mol (1 bar and 298.15 K) a) What is the standard enthalpy of reaction for the above reaction? Assume that O2(g) and CO2(g) behave as ideal gas and use CV,m = 5R/2 for both b) What is the standard enthalpy of formation of C60(s)

Calculate ∆S⁰R for the reaction 3H2(g) + N2(g) = 2NH3(g) at 700 K given the following:...

Calculate ∆S⁰R for the reaction 3H2(g) + N2(g) = 2NH3(g) at 700 K given the following: S⁰298K for H2g = 197.7 J K-1 mol -1 S⁰298K (N2g) = 191.6 J K-1 mol -1 S⁰298K (NH3g) = 130.7 J K-1 mol -1 Cp (H2g) in J K-1 mol -1 = 22.7 + 4.4 x 10-2 T – 1.1x10-4 T2 Cp (N2g) in J K-1 mol -1 = 30.8 – 1.2 x 10-2 T + 2.4 x10-5 T2 Cp (NH3g) in J...

2-Assuming ideal gas and constant Cp, calculate [capital delta S with hat on top] (in kJ/(kg?K))...

2-Assuming ideal gas and constant Cp, calculate [capital delta S with hat on top] (in kJ/(kg?K)) for a process where nitrogen is heated from 200 K to 800 K while changing the pressure from 2000 kPa to 1000 kPa. 1-Using the thermodynamic tables, calculate [capital delta S with hat on top] (in kJ/(kg?K)) for a process where nitrogen is heated from 200 K to 800 K while changing the pressure from 2000 kPa to 1000 kPa.

When heated, calcium carbonate (calcite) decomposes to form calcium oxide and carbon dioxide gas CaCO3(s) <---->...

When heated, calcium carbonate (calcite) decomposes to form calcium oxide and carbon dioxide gas CaCO3(s) <----> CaO(s) + CO2(g) Using the data below, calculate the equilibrium partial pressure of CO2(g) over a mixture of solid CaO and CaCO3 at 500 ◦C if ∆CP,m for the reaction is independent of temperature over the temperature range between 25 ◦C and 500 ◦C ...............................CaO(s)..........CO2(g).............. CaCO3(s) ∆H◦ f (kJ/mol) .......−635.09 ......−393.51 ............−1206.92 S◦ m (J / mol K) ......39.75 .........213.74 .................92.90 CP,m (J /...

Consider the reaction CO (g) + 0.5 O2 (g) -> CO2 (g). Compute the molar delta...

Consider the reaction CO (g) + 0.5 O2 (g) -> CO2 (g). Compute the molar delta H (in kJ/mol) for this reaction at 298 K and a pressure of 30 bar. Joule-Thomson coefficients and heat capacities are listed in the table below: Compound Cp (cal mol^-1 K^-1) Joule-thomson coefficient (K/bar) CO 6.3423 + 0.0018363 T 1.20 O2 6.148 + 0.003102 T 1.15 CO2 6.369 + 0.0101 T 1.10

Consider the reaction CO (g) + 0.5 O2 (g) -> CO2 (g). Compute the molar delta...

Consider the reaction CO (g) + 0.5 O2 (g) -> CO2 (g). Compute the molar delta H (in kJ/mol) for this reaction at 298 K and a pressure of 30 bar. Joule-Thomson coefficients and heat capacities are listed in the table below: Compound Cp (cal mol^-1 K^-1) Joule-thomson coefficient (K/bar) CO 6.3423 + 0.0018363 T 1.20 O2 6.148 + 0.003102 T 1.15 CO2 6.369 + 0.0101 T 1.10

Carbon dioxide is an important greenhouse gas. Calculate the enthalpy change for a 66.5g sample of...

Carbon dioxide is an important greenhouse gas. Calculate the enthalpy change for a 66.5g sample of CO2 heated from 0.6 C to 50.0 C at constant pressure assuming (a) that Cp,m is not a f(T) and (b) where Cp,m is a f(T). Cp,m(CO2) = 27.11 J/molK at 25 C and a = 44.22 J/mol K, b=0.00879 J/molK^2 and c=-8.62x10^5 K/mol. How does this energy change compare to the average intermolecular force?

3. 10.0 moles of ideal gas cloud has an initial pressure of 1.00 bar, initial volume...

3. 10.0 moles of ideal gas cloud has an initial pressure of 1.00 bar, initial volume of 100.0L and temperature of 25.0ºC. The cloud expands adiabatically to a final volume of 1000.0L. Cp,m= 20.79 J / mol K (Cp,m is molar heat capacity and constant pressure) a. (10 pts) What is the final pressure of the gas cloud? b. (10 pts) What is the final temperature of the gas cloud? c. (10 pts) What is the change in entropy for...

An ideal gas is brought through an isothermal compression process. The 3.00 mol3.00 mol of gas...

An ideal gas is brought through an isothermal compression process. The 3.00 mol3.00 mol of gas goes from having an initial volume of 240.7 cm3240.7 cm3 to 104.6 cm3.104.6 cm3. If 2.210×103 cal2.210×103 cal is released by the gas during this process, what are the temperature ?T of the gas and the final pressure ?f?pf? The gas constant is ?=8.31 J/mol⋅K,R=8.31 J/mol⋅K, and there are 4.19 J/cal.4.19 J/cal. ?=T= K ?

Calculate deltaS for N2 (1 bar, 298 K) --> N2 (32 bar, 1500 K). Assume N2...

Calculate deltaS for N2 (1 bar, 298 K) --> N2 (32 bar, 1500 K). Assume N2 to be an ideal gas. CP = 28.58 + 3.77 x 10-3 T – 0.50 x 105 T-2 J K-1 mol-1