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Presentation transcript:

See updates on slides 1, 2, 3, and 8 Chem. 1B – 10/13 Lecture See updates on slides 1, 2, 3, and 8

Announcements I Exam 2: Two Weeks from Today (10/27) Mastering Lab: Some confusion if you pay detailed attention to text (will discuss today) Lab: Quiz 6 – on Exp 3 or 4 (pre-lab) plus solubility/complex ion Lab Midterm and Exp 3 report on Wed./Thurs. Note: Syllabus says Lab midterm is on Exp 1, 2, 5, and 7, but will also have questions related to pre-lab on Experiment 3

Announcements II Today’s Lecture Solubility – use for qualitative analysis (skipped last time) Thermodynamics Reviewing Ch. 6 Spontaneous Reactions Entropy Gibb’s Free Energy

Chem 1B – Aqueous Chemistry Solubility (Qualitative Analysis) Mixtures of ions (anions or cations) can be separated by successive addition of counter ions that lead to selective precipitation Example scheme in section 16.7 is for cations Successive treatments typically start with mostly soluble anions (Cl-) and go to less and then less soluble anions (go to text figure – next slide) 4

A General Qualitative Analysis Scheme Figure 16.16 pg 118

Chem 1B – Aqueous Chemistry Solubility (Qualitative Analysis) What is the difference between acid insoluble sulfides and base insoluble sulfides? Main difference is value of Ksp Examples: Cu2+ (acid insoluble) and Fe2+ (base insoluble) Ksp = 1.27 x 10-36 for CuS vs. 1.72 x 10-19 for FeS (Table 16.2) Footnote at bottom of table explains Ksp is for the reaction: CuS(s) + H2O(l) ↔ Cu2+(aq) + HS-(aq) + OH-(aq) NOTE: Mastering homework seems to not have seen the footnote – in their method of doing sulfide problems (which is based on a standard – and wrong reaction of e.g. NiS(s) ↔ Ni2+(aq) + S2-(aq) ) - Calculate solubility of Fe2+ and Cu2+ at pH = 0 and pH = 13 in 1 M HS- (total S2- concentration) 6

Chem 1B – Thermodynamics Chapter 17 Chapter 6 – Review Types of Energy: kinetic energy (associated with motion) potential energy (stored energy – e.g. ball at the top of a hill) Chemical energy (a type of stored energy) Heat (a molecular scale type of kinetic energy) Conservation of Energy Energy can change forms – but can not be created or destroyed 7

Chem 1B – Thermodynamics Chapter 17 Chapter 6 – Review II Systems and Surroundings used to define energy transfers example: system with reaction that produces heat (conversion from chemical energy) can heat surroundings Enthalpy (H) Energy related to heat DH = qp (heat in a constant pressure system) Endothermic reaction means DH > 0, means heat from surrounding used for reaction Exothermic reaction means DH < 0, means heat from reaction goes to surroundings 8

Chem 1B – Thermodynamics Chapter 17 Chapter 17 – Overview Spontaneous and Non-Spontaneous Processes: Entropy: A measure of disorder Gibbs Free Energy Entropy and Gibbs Free Energy Changes Associated with Reactions Relating Gibbs Free Energy to Equilibrium Constants 9

Chem 1B – Thermodynamics Chapter 17 – Spontaneous Processes Thermodynamical Definition of Spontaneous A spontaneous process is one that will eventually occur (actually has nothing to do with speed of occurrance) Examples of spontaneous processes: freezing of water droplet at -5°C dissolution of 0.1 moles of NH4NO3 in 1.0 L of water (solubility is much higher) oxidation of Fe(s) in air Non-spontaneous process: one that won’t occur without intervention 10

Chem 1B – Thermodynamics Chapter 17 – Spontaneous Processes Thermodynamical Definition of Spontaneous Most, but not all, spontaneous processes are exothermic (e.g. H2(g) + O2(g) ↔ H2O(l)) Non-spontaneous process: one that won’t occur without intervention Example: splitting water to H2(g) and O2(g) (can be done through electrolysis, but then needs external energy) 11

Chem 1B – Thermodynamics Chapter 17 – Entropy A few reactions that occur spontaneously are endothermic (e.g. NH4NO3(s) ↔ NH4+(aq) + NO3-(aq)) How can a process occur if it takes energy? There must be some trade off that makes it likely to occur Process is an increase in disorder (entropy) For example, we can see that a desk will have a natural tendency to becoming disordered and that it takes energy to clean it 12

Chem 1B – Thermodynamics Chapter 17 – Entropy The Second Law of Thermodynamics: For any spontaneous process, the entropy of the universe increases (DSuniv > 0) Thus the natural tendency is for a process to occur if it increases entropy This can explain why some reactions occur even if DH is positive such as: NH4NO3(s) ↔ NH4+(aq) + NO3-(aq) 13

Chem 1B – Thermodynamics Chapter 17 – Entropy A macroscopic analogy to entropy would be to have a box of 50 ping pong balls with half white and half black Even if placed on two separate halves of the box, if the box were shaken to mix the balls, roughly half of each color would be expected in each half v v final state initial state 14

Chem 1B – Thermodynamics Chapter 17 – Entropy Entropy in Chemical Systems From a molecular scale view, a system that appears more randomly assembled has higher entropy (can have more possible “states”) Highly ordered Highly disordered Low Entropy High Entropy S = 0 Crystalline solid (T = 0K) Crystalline solid (T > 0K) Amorphous solid liquid gas large compound various small compounds N2O4(g) vs. 2NO2(g) vs. 2O2 (g) + N2(g) vs. 4O (g) + 2N(g) note: gases shown are relative (still at higher entropy vs. liquids/solids) 15

Chem 1B – Thermodynamics Chapter 17 – Entropy Determine the sign of entropy change for the following reactions: Entropy Examples: (Is ΔS > or < 0?) H2O(l) ↔ H2O(g) H2O(s) ↔ H2O(l) NaCl(s) ↔ Na+(aq) + Cl-(aq) 2H2(g) + O2(g) ↔ 2H2O(g) N2(g) + O2(g) ↔ 2NO(g) ΔS > 0 ΔS > 0 ΔS > 0 ΔS < 0 ΔS > 0 16

Chem 1B – Thermodynamics Chapter 17 – Entropy Quantifying Entropy Changes (ΔS) From 2nd Law of thermodynamics, we know DSuniv ≥ 0 and DSuniv = DSsys + DSsurr Thus for a process in which ΔSsys < 0 (e.g. I2(g) ↔ I2(s)), we know DSsurr > 0 In our particular example, energy (or enthalpy) is evolved in the process (I2(g) ↔ I2(s)) we can set these equal in DSsurr = -qsys/T or under constant pressure, DSsurr = - DHsys/T 17

Chem 1B – Thermodynamics Chapter 17 – Entropy Quantifying Entropy Changes (ΔS) II For a particular process, we also can look up standard entropy values (S°) for reactants and products (see Appendix II B) These are under standard conditions (25°C/1 atm for gases/1 M for solutions) Example: I2(g) ↔ I2(s) S°(I2(s)) = 116.14 J mol-1 K-1 and S° (I2(g)) = 180.79 J mol-1 K-1 so for rxn DS° = 116.14 – 180.79 = -64.65 J mol-1 K-1 18

Chem 1B – Thermodynamics Chapter 17 – Gibbs Free Energy We have identified two processes generally (but not always) associated with spontaneous processes: Exothermic processes (DH < 0) Processes with an increase in entropy (DS > 0) Is there a way in which we can always predict a reaction direction? YES. We use the change in Gibbs Free Energy 19

Chem 1B – Thermodynamics Chapter 17 – Gibbs Free Energy Basis and Definition of Gibbs Free Energy: Mathematical Basis for Gibbs Free Energy: DSuniv = DSsys + DSsurr and DSsurr = -DHsys/T This means DSuniv = DSsys – DHsys/T or -TDSuniv = DHsys – TDSsys = DG Definition of Gibbs Free Energy = G = H – TS under constant T, DG = DH – TDS 20