1 / 44

CHEM 212

CHEM 212. Chapter 3. By Dr. A. Al-Saadi. Introduction to The Second Law of Thermodynamics. The two different pressures will be equalized upon removing the partition. This is a natural (usually irreversible) process or called “ spontaneous ”. Introduction to The Second Law of Thermodynamics.

mcbridek
Télécharger la présentation

CHEM 212

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. CHEM 212 Chapter 3 By Dr. A. Al-Saadi

  2. Introduction to The Second Law of Thermodynamics The two different pressures will be equalized upon removing the partition. This is a natural (usually irreversible) process or called “spontaneous”.

  3. Introduction to The Second Law of Thermodynamics The irreversible natural “spontaneous”process takes place by the heat passing from the hot object to the cold one until we have T1 = T2. The process that is another way around is called “nonspontaneous” and has to be done reversibly. Hot solid Cold solid T1 T2 Where T1> T2

  4. Introduction to The Second Law of Thermodynamics 2H2(g) + O2(g)  2H2O(l) Is reaction spontaneous? It is spontaneous in going from left to right. For the reaction to go from right to left, work has to be done on H2O(l) to get the gases, and it is nonspontaneous.

  5. Entropy (S) A measurement of spontaneity is the entropy. If a process occurs reversible from state A to state B with infinitesimal amounts of heat (dqrev) absorbed at each stage, the “entropy change” is defined as:

  6. Defining Entropy on the Basis of Steam Engine It is impossible for an engine to perform work by cooling a portion of matter to a temperature below that of the coldest part of the surroundings.

  7. Historical Development of Steam Engines • Newcomen steam engine: • One-cylinder steam engine. • Efficiency of converting heat into work is only 1%

  8. Historical Development of Steam Engines • Watt’s steam engine: • Two-cylinder steam engine, mainly a cylinder (kept at Th) and a condenser (kept at Tc). • Efficiency of converting heat into work is only 10%

  9. Historical Development of Steam Engines • Watt’s steam engine: • Two-cylinder steam engine, mainly a cylinder (kept at Th) and a condenser (kept at Tc). • Efficiency of converting heat into work is only 10%

  10. The Carnot Engine • It is a theoretical engine explaining the process in terms of Th and Tc. • It assumes: • An ideal engine. • An ideal gas, and • A reversible process. Carnot showed that such an engine would have the maximum possible efficiency for any engine working between Th and Tc.

  11. The Carnot Engine • Four processes being done reversibly: • Isothermal expansion at Th. • Adiabatic expansion. • Isothermal compression at Tc. • Adiabatic compression.

  12. The Carnot Cycle Pressure-volume diagram for the Carnot cycle. AB and CD are isotherms. BC and DA are adiabatics

  13. The Carnot Cycle The Carnot cycle for 1 mole of an ideal gas that starts at 10.0 bar and 298.15 K with the value of CP/CV = γ = 1.40 (used for N2 gas)

  14. The Carnot Cycle

  15. The Net Work from Carnot Cycle

  16. Example 3.1

  17. The Concept of Entropy qb= qc+ dq Tc is unchanged q = 0 Tc=Ta+dT

  18. The Concept of Entropy Entropy is a measure of the disorder of the system. The change in the entropy (ΔS) indicates whether a change in the disorder of the system takes place or not. The sign of ΔS also indicated whether the disorder of the system increases or decreases.

  19. The Concept of Entropy Inequality of Clausius: The change in entropy is generally given by: Any change that occurs irreversibly in nature is spontaneous and therefore is accompanied with a net increase in entropy. The energy of the universe is constant. The entropy of the universe tends always towards maximum.

  20. Molecular Interpretation of Entropy When a spontaneous change takes place, the disorder of the system increases and its entropy, as a result, increases. Entropy is a measure of disorder. Example 1: Mixing solute and solvent Mixing process is a spontaneous process that increases the disorder of the system. Thus, entropy is expected to increase and ΔS is +ve.

  21. Molecular Interpretation of Entropy • Example 2: Phase change • Melting of solid. (ΔS is +ve) • Freezing of a liquid. (ΔS is -ve) • Evaporation of liquid. (ΔS is +ve) • Example 3: Chemical reactions • H2(g)  2H(g) (ΔS is +ve) • 2NH2(g)  3H2(g) + N2(g) (ΔS is +ve) • Generally, in gaseous reactions, as the number of molecules increases (less pairing), entropy would increase. That is because less pairing involves more disorder and less restrictions.

  22. Entropy of Mixing The mixing of ideal gases at equal pressures and temperatures

  23. Calculation of Entropy Change

  24. Calculation of Entropy Change for Solids and Liquids

  25. Calculation of Entropy Change

  26. Calculation of Entropy Change

  27. The Third Law of Thermodynamics Nernst’s heat theorem states that: ΔS = 0 at the absolute zero provided that the states of the system are in thermodynamic equilibrium. Equilibrium is slowly and barely achieved at extremely low temperatures. The 3rd law of thermodynamics: The entropies (Sa , Sb , Sc , …) of all perfectly crystalline substances (thermodynamic equilibrium) must be the same at the absolute zero (Sa = Sb = Sc = …).

  28. Achieving Very Low Temperatures 1- Expansion of the molecules to reduce the intermolecular forces (cooling to 1K). 2- Magnetization (entropy decrease and thus flow of heat from the sample to the surrounding) and then demagnetization (done after isolating the system “adiabatic step” causing cooling) . (cooling to about 0.005K)

  29. Absolute Entropies • The absolute entropy of a substance can be calculated at another temperature by: • cooling down that substance to nearly the absolute zero, and then • increasing its temperature through reversible steps until the desired temperature is attained.

  30. Absolute Entropies

  31. Entropy Change of a Chemical Reaction Absolute entropies for substances are tabulated at standard conditions. http://bilbo.chm.uri.edu/CHM112/tables/thermtable.htm

  32. Conditions for Equilibrium The position of equilibrium must correspond to a state of maximum total entropy.

  33. Molecular Interpretation of Gibbs Energy (G) In spontaneous processes at constant T and P, system moves towards a state of minimum Gibbs energy. (dG < 0) In the condition of equilibrium at constant T and P, there is no change in Gibbs energy (dG = 0)

  34. Molecular Interpretation of Gibbs Energy (G) Consider the reaction H2↔ 2H at T=300K H2 2H (nonspontaneous) 2H  H2 (spontaneous) For the spontaneous 2H  H2 reaction: ΔG is –ve (The system approaches equilibrium as G goes to minimum). To show this in terms of enthalpy and entropy changes: ΔG = ΔH – TΔS ΔH is –ve (The reaction loses heat). ΔS is –ve, (More ordered arrangement as H2 molecules are produced). ΔH – TΔS < 0 < 0 Thus, the affecting parameter (the weighting factor) is T: T is small, ΔH > TΔS, andΔG will be –ve (spontaneous). T is too large, ΔH < TΔS, andΔG will be +ve (nonspontaneous dissociation of H2 molecules).

  35. The Contribution to Spontaneous Change ΔG = ΔH – TΔS Enthalpy Change Entropy Change Spontaneous? ΔH < 0 (Exothermic) ΔS > 0 ΔH < 0 (Exothermic) ΔS < 0 ΔH < 0 (Exothermic) T = 0 ΔH > 0 (Endothermic) ΔS > 0 ΔH > 0 (Endothermic) ΔS < 0 ΔH > 0 (Endothermic) T = 0 Yes (ΔG < 0) Yes, if |TΔS| < |ΔH| Yes (ΔG < 0) Yes, if |TΔS| > |ΔH| No (ΔG > 0) No (ΔG > 0)

  36. The vaporization of water at 100°C. (a) Liquid water at 100°C is in equilibrium with water vapor at 1 atm pressure. (b) Liquid water at 100°C is in contact with water vapor at 0.9 atm pressure, and there is spontaneous vaporization

  37. ΔrGº for Chemical Reactions Determine the Delta G under standard conditions using Gibbs Free Energies of Formation found in a suitable thermodynamic table for the following reaction: 4HCN(l) + 5O2(g) ---> 2H2O(l) + 4CO2(g) + 2N2(g) http://members.aol.com/profchm/t_table.html 2 moles ( -237.2 kj/mole) = -474.4 kj = Standard Free Energy of Formation for two moles H2O(l) 4 moles ( -394.4 kj/mole) = -1577.6 kJ = Standard Free Energy of Formation for four moles CO2 (g) 2 moles(0.00 kj/mole) = 0.00 kJ = Standard Free Energy of Formation for 2 moles of N2(g) Standard Free Energy for Products = (-474.4 kJ) + (-1577.6 kJ) + 0.00 = -2052 kJ 4 moles ( 121 kj/mole) = 484 kJ = Standard Free Energy for 4 moles HCN(l) 5 moles (0.00 kJ/mole) = 0.00 kJ = Standard Free Energy of 5 moles of O2(g) Standard Free Energy for Reactants = (484) + (0.00) = 484 kJ Standard Free Energy Change for the Reaction = Sum of Free Energy of Products - Sum of Free Energy of Reactants = (-2052 kJ) - (484 kJ) = -1568 kJ

  38. Maxwell Relations Important Relationships ; ; ; ;

  39. Maxwell Relations

  40. Maxwell Relations

  41. Applications of Maxwell Relations Thermal expansion coefficient (α): During heat transfer, the energy that is stored in the intermolecular bonds between atoms changes. When the stored energy increases, so does the length of the molecular bond. As a result, solids typically expand in response to heating and contract on cooling. This response to temperature change is expressed as its coefficient of thermal expansion.

  42. Applications of Maxwell Relations Prove that for 1 mole of a van der Walls gas, the internal pressure (∂U/∂V)T is equal to a/V2m.

  43. Fugacity

  44. Fugacity

More Related