Chapter 2 The First Law Unit 5 state function and exact differentials Spring 2009
State function and Path function State function a property that is independent of how a sample is prepared. example : T, P, U, H … Path function a property that is dependent on the preparation of the state. depends on the path between the initial and final states example : W, q …
Example 2.7 Calculating work, heat, and internal energy Consider a perfect gas inside a cylinder fitted with a piston. Let the initial state be T, V i and the final state be T,V f. The change of state can be brought about in many ways, of which the two simplest are the following: Path 1, in which there is free expansion against zero external pressure; Path 2, in which there is reversible, isothermal expansion. Calculate w, q, and ∆U and Hfor each process.
Example 2.7 Path 1isothermal free expansion Isothermal U=0, H=0 U=q+ w = 0q=- w free expansion w q Path 2isothermal reversible expansion Isothermal U=0, H=0 U=q+ w = 0q=- w reversible expansion
Self Test 2.8 Calculate the values of q, w, and ∆U, H for an irreversible isothermal expansion of a perfect gas against a constant nonzero external Irreversible isothermal expansion Isothermal U=0, H=0 U=q+ w = 0q=- w Irreversible expansion w P ex V q P ex V
Change in internal energy, U
Internal pressure Constant-pressure heat capacity
Internal pressure The variation of the internal energy of a substance as its volume is changed at constant temeperature. For a perfect gas T For real gases attractive force T repulsive force T
Internal pressure
Joule experiment Expands isothermally against vacuum (p ex =0) w=0, q=0 so U=0 and T =0
U at constant pressure Expansion coefficient the fraction change in volume with a rise in temperature Isothermal compressibility the fractional change in volumewhen the pressure increases in small amount
E 2.32 b The isothermal compressibility of lead at 293 K is 2.21 × 10 −6 atm −1. Calculate the pressure that must be applied in order to increase its density by 0.08 per cent.
Example 2.8 Calculating the expansion coefficient of a gas Derive an expression for the expansion coefficient of a perfect gas.
U at constant pressure For perfect gas
Change in enthalpy, H (chain relation) Joule-Thomson coefficient =
Joule-Thomson coefficient, A vapour at 22 atm and 5°C was allowed to expand adiabatically to a final pressure of 1.00 atm; the temperature fell by 10 K. Calculate the Joule–Thomson coefficient, µ, at 5°C, assuming it remains constant over this temperature range.
Joule-Thomson coefficient, For perfect gases = 0 For real gases 0gas cools on expansion 0gas heats on expansion Inversion temperature
Exercise 2.29a When a certain freon used in refrigeration was expanded adiabatically from an initial pressure of 32 atm and 0°C to a final pressure of 1.00 atm, the temperature fell by 22 K. Calculate the Joule–Thomson coefficient, µ, at 0°C, assuming it remains constant over this temperature range.
Joule-Thomson effect Cooling by isenthalpic expansion Adiabatic process q=0, U= w P i > P f On the left isothermal irreversible compression P i,V i,T i → P i,0,T i w 1 = -p i ( 0 - V i )= p i V i On the right isothermal irreversible expansion P f,0,T f → P f,V f,T f w 2 = -p f ( V f - 0 )= -p f V f
Joule-Thomson effect Cooling by isenthalpic expansion w = w 1 + w 2 = p i V i - p f V f w = U=U f -U i = p i V i - p f V f U f + p f V f = U i + p i V i H f = H i Joule-Thomson effect is an isenthalpic process
Isothermal Joule-Thomson coefficient
Liquefaction of gases
Review 1 Define internal pressure T Prove that, for ideal gas, T = 0
Review 2 Define Expansion coefficient Define Isothermal compressibility T Prove that for ideal gas = 1/T T = 1/p
Review 3 Define Joule-Thomsom coefficient Prove that Joule-Thomson experiment is an isentahlpic process. Explain the principle of using Joule-Thomson effect to liquefy gases.