Calculate Z and V of a gas at 350 k and 15 bar using the truncated...

Calculate z and v of a gas at 350 k and 15 bar using the truncated...

Calculate z and v of a gas at 350 k and 15 bar using the truncated virial equation with the following experimental values of virial coefficients: z=PV/RT=1+B/V+C/V^2 B=-208 cm^3 mol -1, C=4378 cm^6 mol^-2

Calculate V and Z for methyl chloride at 100 ° C and 55bar for the ideal...

Calculate V and Z for methyl chloride at 100 ° C and 55bar for the ideal gas equation, by the equation of virial. Data: R = 83.14 cm 3 bar/molK; viral coefficient B equals -242.5 cm3/mol.

-Show that for the truncated virial equation, Z = 1 + BP/RT, the fugacity is given...

-Show that for the truncated virial equation, Z = 1 + BP/RT, the fugacity is given by f = eZ-1 ⋅P. Further show that f ≈ Z⋅P when Z is near unity (make use of a series approximation). -Show that for a van der Waals gas, with Z near unity, the second virial coefficient is given by B = (b – a/RT). -Use the derived relationship to calculate the fugacities and fugacity coefficients for hydrogen and for carbon dioxide gases...

CALCULATE THE FUGACITY COEFFICIENT OF TOLUENE AT 50 °C & 25 KPA USING THE VIRIAL EQUATION...

CALCULATE THE FUGACITY COEFFICIENT OF TOLUENE AT 50 °C & 25 KPA USING THE VIRIAL EQUATION OF STATE TRUNCATED AFTER THE SECOND TERM. SUCH AN EQUATION OF STATE IS GIVEN BY THE FOLLOWING EXPRESSION: Z=1+ (BP/RT), WHERE THE SECOND VIRIAL COEFFICIENT (B) FOR TOLUENE IS -1,860 CM3/MOL.

12 moles of a gas is compressed isothermally and reversibly from 400 K , 1 bar...

12 moles of a gas is compressed isothermally and reversibly from 400 K , 1 bar to 1/2th of its original volume. Initial volume of the gas was measured at 120 cm^3. Using the truncated virial EOS, calculate the required work for the compression.

At 150 °C, a hypothetical gas has second and third virial coefficients of: B = −145.9...

At 150 °C, a hypothetical gas has second and third virial coefficients of: B = −145.9 cm3 mol C =15,650 cm6 mol2 Use the two-term virial equation to determine how much work (in kJ/mol) is done in a mechanically reversible, isothermal process. The gas is compressed from 1 bar to 10 bar at 150°C.

Calculate the volume for n-butane at 313.28℃ and 75.92 bar according to: 1. The ideal gas...

Calculate the volume for n-butane at 313.28℃ and 75.92 bar according to: 1. The ideal gas equation 2. The theorem of corresponding states 3. Generalised correlation for the Compressibility factor 4. Generalised correlation for the Second virial coefficient.

1. Find values of residual enthalpy for ethylene at 400 K and 25 bar using Peng-Robinson...

1. Find values of residual enthalpy for ethylene at 400 K and 25 bar using Peng-Robinson equation of state. 2. Find values of residual Gibbs energy, enthalpy and entropy for n-heptane at 500 K and 100 bar using Virial equation of state. 3. Estimate the values of Compressibility factor, enthalpy and entropy for Benzene and cyclohexane if it compressed from 650 K and 60 bar to 500 K and 110 bar. 4. Calculate ΔU and ΔH for 1 kg of...

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

A system of water (1) and methane (2) exists as two phases at 298 K and...

A system of water (1) and methane (2) exists as two phases at 298 K and 23.23 atm. Rigby and Prausnitz (1968) reported the water mole fraction in the vapor phase as 1.483 × 10−3. The vapor phase is represented by the virial equation of state with the following parameters: B11 = −1165 cm3/mol, B22 = −43.4 cm3/mol. (a) Estimate the liquid phase composition. (b) Determine the second virial cross coefficient, B12. The vapor pressure of water at 298 K...