Why does a gas have more work when adjusted for idealness via Van der Waals equation...

_{Why does a gas have more work when adjusted for idealness
via Van der Waals equation and Dieterici versus ideal gas equation.
I have solved a problem where the gas has more work done when
adjusting for idealness rather than just using the ideal gas
equation. Why, in terms of intramolecular or intermolecular forces
does this occur?}

Expert Solution

Van der waal’s equation

Thought the equation PV=RT was arrived at first experimentally and then theoretically, yet it fails to explain the behaviour of real gases. van der Waals attributed the deviation of real gases from gas equation to the following faulty assumptions of the kinetic theory:

(i) The actual volume of the gas molecules is negligible as compared with the total volume of the gas.

(ii) The gas molecules do not exert any appreciable attraction on each other.

Both these assumptions are not true at high pressure and low temperature. At high pressure the volume is reduced to a great extent and the actual volume of the molecules cannot be supposed as negligible under such conditions. Moreover, the molecules come closer and the attractive force between them should also be taken into consideration.

Van der Waals introduced the necessary corrections as follows:

(a) Volume correction: At higher pressure, the volume is much reduced and at this state the volume of gas molecules no longer remains negligible in comparison with the total volume V occupied by the gas. Thus the free space available for motion of molecules is reduced. If v be the volume of the molecules at rest, effective volume when they are in motion must be greater. It has been calculated to be approximately four times the actual volume of the molecules.

I. e.

4v and is generally denoted by b. Therefore the actual volume available in which the molecules are free to move will be

= Total volume — Effective volume.

i.e., correct volume(V – b)

(b) Pressure correction: The pressure of a gas is due to the hits of the molecules on the walls of the containing vessel. The attractive force between the molecules comes into play when the molecules are brought close together by compressing the gas. A molecule in the body of the gas is attracted in all the directions when forces acting in opposite directions cancel out, but a molecule, the boundary of the gas is subjected to an inward pull due to unbalanced molecular attraction.

In this way some of the energy of the molecule about to strike the wall of the vessel is used up in overcoming this inward pull. Therefore, it will not strike the opposite wall with the same force. The observed pressure consequently will be less than the ideal pressure. Therefore the ideal pressure, Pi will be equal to observed pressure P plus a pressure correction, Pa depending upon the attractive forces,

I.e. Pi = P + Pa

queen_honey_blossom answered 2 years ago

Van der Waals Gases Under what conditions of volume does a van der Waals gas behave...

Van der Waals Gases Under what conditions of volume does a van der Waals gas behave like an ideal gas? Use the van der Waals equation of state to justify your answer.

Use the van der Waals equation and the ideal gas equation to calculate the volume of...

Use the van der Waals equation and the ideal gas equation to calculate the volume of 1.000 mol of neon at a pressure of 500.0 bar and a temperature of 355.0 K. (Hint: One way to solve the van der Waals equation for V is to use successive approximations. Use the ideal gas law to get a preliminary estimate for V V in ideal gas V in van der waal gas

In the van der Waals model of a gas, as compared to an ideal gas, a....

In the van der Waals model of a gas, as compared to an ideal gas, a. Intermolecular forces decrease the pressure, but finite molecular volume increases it b. Both intermolecular forces and finite molecular volume increase the pressure c. Both intermolecular forces and finite molecular volume decrease the pressure d. Intermolecular forces increase the pressure, but finite molecular volume decreases it

Derive constants for Van der Waals equation of state. Why is this equation used for? (Detailed...

Derive constants for Van der Waals equation of state. Why is this equation used for? (Detailed explanation and derivation)

what's πt of van der waals gas? and how to solve this

What is the role of the constants a and b in the van der waals equation...

What is the role of the constants a and b in the van der waals equation in terms of the kinetic molecular theory?

The van der Waals equation for 1 mole of gas is given by (p +av-2)(v -...

The van der Waals equation for 1 mole of gas is given by (p +av-2)(v - b) = RT. In general, curves of p versus v forvarious values of T exhibit a maximum and a minimum at the twopoints where (δp/δv)T = 0. The maximum and minumum coalesceinto a single point on that curve where(δ2p/δv2)T = 0 inaddition to (δp/δv)T = 0. This point is calledthe "critical point" of the substance and its temperature,pressure, and molar volume are denoted by...

For oxygen gas, the van der Waals equation of state achieves its best fit for a=0.14...

For oxygen gas, the van der Waals equation of state achieves its best fit for a=0.14 N⋅m^4/mol^2 and b=3.2×10^(−5) m^3/mol 1.Determine the pressure in 2.0 mol of the gas at 10 ∘C if its volume is 0.24 L , calculated using the van der Waals equation. 2. Determine the pressure in 2.0 mol of the gas at 10 ∘C if its volume is 0.24 L , calculated using the ideal gas law.

Using Van der Waals gas equation, describe enthalpy, entropy, Helmholtz free energy, Gibbs free energy as...

Using Van der Waals gas equation, describe enthalpy, entropy, Helmholtz free energy, Gibbs free energy as a function of temperature and volume.

Hydrogen, acting as a van der Waals gas (EOS shown below), is compressed in an isothermal...

Hydrogen, acting as a van der Waals gas (EOS shown below), is compressed in an isothermal closed system process from 6.236m3/kg to 0.629m3/kg at 300K. What is the change in specific entropy of the gas? (use the entropy change relation in chapter 12) P = RT/( v − b) − a/( v^2) (1) a = 27R^2Tcrit^2/(64Pcrit) (2) b = RTcrit/ (8Pcrit) (3) Following example 12-7 in the book the change in internal energy of a van der Waals gas for...

Question