Find ∆Ssys, ∆Ssurr, q, w, and ∆U for the reversible isothermal expansion of 3.000 mol of...

Suppose 4.00 mol of an ideal gas undergoes a reversible isothermal expansion from volume V1 to...

Suppose 4.00 mol of an ideal gas undergoes a reversible isothermal expansion from volume V1 to volume V2 = 8V1 at temperature T = 300 K. Find (a) the work done by the gas and (b) the entropy change of the gas. (c) If the expansion is reversible and adiabatic instead of isothermal, what is the entropy change of the gas?

Calculate the values of q, w, delta U, and delta H for the reversible adiabatic expansion...

Calculate the values of q, w, delta U, and delta H for the reversible adiabatic expansion of 1 mole of a monoatomic ideal gas from 5.00 m^3 to 25.0 m^3. The temperature of the gas is initially 298K.

7. 1.55 moles of Argon gas undergo an isothermal reversible expansion from an initial volume of...

7. 1.55 moles of Argon gas undergo an isothermal reversible expansion from an initial volume of 5.00 L to 105. L at 300 K. Calculate the work done during this process using: (a) the ideal gas equation, and (b) the van der Waals equation of state. Van der Waals parameters for Ar are available in the back of the book. Compare the two results, what percentage of the work done by the van der Waals gas arises due to having...

a) Calculate delta S(system) for the reversible heating of 1 mol of ethane from 298K to...

a) Calculate delta S(system) for the reversible heating of 1 mol of ethane from 298K to 1500 K at constant pressure. Use Cp = 5.351 + 177.669x10-3 T – 687.01x10-7 T ^2 + 8.514x10-9 T ^3 (J/mol K). Consider the reversible Carnot cycle discussed in class with 1 mol of an ideal gas with Cv=3/2R as the working substance. The initial isothermal expansion occurs at the hot reservoir temperature of Thot=600C from an initial volume of 3.50 L to a...

6.Predict whether the values of q, w , U and H are positive, zero, or negative...

6.Predict whether the values of q, w , U and H are positive, zero, or negative for each of the following processes: Metling of ice at 1 atm and 273K Melting of solid cylcohexane at 1 atm and the normal melting point Reversible isothermal expansion of an ideal gas Reversible adiabatic expansion of an ideal gas For most substances, the volume increases upon melting, but for the ice melting to water under the given conditions, the volume decreases. In all...

Derive an expression for the isothermal reversible expansion of a van der Waals gas. Account physically...

Derive an expression for the isothermal reversible expansion of a van der Waals gas. Account physically for the way in which the coefficients a and b appear in the expression. Using Maple, plot the expression along with that for an ideal gas. For the van der Waals gas, use a case first where a = 0 and b = 5.11 x 10-2 mol-1 and where a = 4.2 L2 atm mol-2 and b = 0. Take Vi = 1.0 L,...

A 1.89 mole sample of Ar undergoes an isothermal reversible expansion from an initial volume of...

A 1.89 mole sample of Ar undergoes an isothermal reversible expansion from an initial volume of 2.00 L to a final volume of 85.0 L at 308 K . Part B Calculate the work done in this process using the van der Waals equation of state. Express your answer using three significant figures. Part C What percentage of the work done by the van der Waals gas arises from the attractive potential? Express your answer using two significant figures.

1 mole of a gas undergoes a mechanically reversible isothermal expansion from an initial volume 1...

1 mole of a gas undergoes a mechanically reversible isothermal expansion from an initial volume 1 liter to a final volume 10 liter at 25oC. In the process, 2.3 kJ of heat is absorbed in the system from the surrounding. The gas follows the following formula: V=RTP+b where V is the molar specific volume, and Tand Pare temperature (abosolute) and gas pressure respectively. Given R= 8.314 J/(mol.K) and b= 0.0005 m3. Evaluate the following a) Work (include sign) b) Change...

A Joule expansion refers to the expansion of a gas from volume V1 to volume V2...

A Joule expansion refers to the expansion of a gas from volume V1 to volume V2 against no applied pressure, and is sometimes also called a free expansion. There is no work done, because the P of -PdV is zero. By insulating the system, this process can be done adiabatically, so there is no change in heat. For an ideal gas, the adiabatic process is also isothermal, so there is no change in thermodynamic energy, ∆U = 0 (which is...

Thermodynamics Question A Joule expansion refers to the expansion of a gas from volume V1 to...

Thermodynamics Question A Joule expansion refers to the expansion of a gas from volume V1 to volume V2against no applied pressure, and is sometimes also called a free expansion. There is no work done, because the P of -PdV is zero. By insulating the system, this process can be done adiabatically, so there is no change in heat. For an ideal gas, the adiabatic process is also isothermal, so there is no change in thermodynamic energy, ∆U = 0 (which...