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UT CH 302 - Lecture notes
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Lecture 3: Solubility of Gases, Liquids, and Solids in Liquids Up to this point we have dealt primarily with pure compounds. The next two sets of lectures deal with what happens when mixtures are created. The lectures are in two parts:  The thermodynamics of what happens when you mix a liquid with a solid, a liquid with a liquid and a liquid with a gas  The interesting properties that are a consequence of mixing—specifically, colligative properties which are properties that depend only on the relative concentrations of the components. These colligative properties include freezing point depression and boiling point elevation, vapor pressure lowering and osmotic pressure. A bit of nomenclature associated with mixing: A solution is the consequence of mixing two or more compounds A solute is the smaller quantity in the solution A solvent is the larger quantity in the solution For example, sea water is a solution consisting of the solute, NaCl, mixed with the solvent, water. Note difference between sections 8.1 – 8.7 and sections 8.8– 8.13 where we changed phases where we mix phases S  G or L  S S + L or G + L and look at ∆G = ∆H – T∆S and look at ∆G = ∆H – T∆S There are some consistent ideas associated with the process of mixing: ∆G = ∆H – T∆S ? ∆G is (–) means that a solid dissolved in solution or that one liquid is miscible with another liquid ∆S is always (+) because mixing substances makesThe complicating issue is the heat of mixing-- ∆H can be either endo or exothermic and is quite varied ∆Hsoln is (+) for NaCl in H2O ∆Hsoln is (–) for Na2SO4 in H2O ∆Hsoln is (–) for O2 in H2O Consider the case that ∆Hmix is negative: since ∆Smix is positive then ∆Gsoln will have to be negative and the reaction happens. Now consider the case that ∆Hmix is positive: in this case the spontaneity of the reaction is temperature dependence and follows the arguments a outlined in Chapter 7 for temperature dependent reaction spontaneity. For example, if a process is endothermic it can be made spontaneous by increasing T. Now let’s look at the three cases of dissolving solids, liquids and gases in a liquid: Case 1: Dissolving salts in water: What happens when a salt in H2O. Is it soluble? The answer is that it depends on the magnitude of ∆Hsolution which in turn depends on the following: ∆Hsolution = ∆Hsolvation or hydration – ∆HC.L.energy Value that goes in Energy of forming a salt crystal ∆G = ∆H – T∆S Energy of solvating an ion These compete and we want solvation effects H H H O - - - - - - - Na+ Cl– O H Cl– Na+ to overcome the crystal lattice energy.Of course, even if the ∆Hsolution ends up slightly endothermic (like NaCl) the positive ∆Smix can make up for it and salt dissolve in water (at high T.) Charge Density and ∆HHydration : Let’s look at things quantitatively and see the relationship between charge density and ∆HHydration Remember from last semester that we predicted: Na – Cl with singly charged ions dissolves easier than Ca – O with doubly charged ions Question: What is rank of ∆HHydration for K+, Na+, Ca++, Al+3 Ion Charge Å Size Charge Density ∆HHydration K+ + 1 1.5 0.6 350 kJ Na+ + 1 1.2 0.9 440 kJ Ca++ + 2 1.1 1.8 1900 kJ Al +++ + 3 0.7 4.4 4800 kJ Which is why K2O dissolves easily in H2O and Al2O3 (glass) does not. The smaller charge density means weaker IMF means easier to melt and dissolve The larger charge density means larger IMF means harder to melt and dissolve Some examples of temperature dependence and solubility are shown. Note that most of the salts exhibit an increasing solubility with temperature, including NaCl which was described above. Two exceptions, sodium sulfate and lithium carbonate have a solubility that decreases with temperature. This occurs for compounds that have an exothermic heat of mixing and will be explained in the Chapter 9 with LeChatelier’s principle.Another table shows more explicitly the inverse relationship between size and hydration energy for ions of like charge. Case 2: Dissolving liquids in liquids First an additional piece of terminology: te Miscible means two liquids that are mixed together form a single phase: ∆G(–) Immiscible means two liquids do not mix together and so two phases exist: ∆G(+) ethanol + H2O H2O Oil two miscible liquids two immiscible liquidsSo how do you know if two compounds will be miscible? The rule you always hear about miscibility is “like dissolves like” which is an easy way of saying that if the intermolecular forces (IMF) are alike, then compounds are miscible and if the IMFs are not alike, they are not miscible (immiscible). The explanation is that if you are replacing one form of intermolecular interaction with another, the more alike the intermolecular forces for the compound that is being added to solution, the less energy that is required for the solution to form. Examples: CH3OH + H2O  Both are H-bond  Miscible H2O + C2H6  1 H-bond, 1 dispersive  Immiscible C2H6 + C3H8  Both are dispersive  Miscible Sample Question: Which of the following is most miscible with H2O? CH3OH or CH3CH2OH or CH3CH2CH2OH Answer: CH3OH is most alike. All have H-bonding but the dispersive part (CH3CH2---) gets bigger and bigger Note, by the way, how many important biomolecules (from nucleotides to fatty acids to amino acids) have both a hydrophilic component (with OH-like bonding) and a hydrophobic component (with hydrocarbon-like bonding.) Micelles and surfactants (soaps) also have these dual features that work in tandem to solubilize dirty (greasy) materials. Dirt  :CH3-(CH2 CH2 CH2 CH2 CH2 CH2 CH2 CH2 - COONa:  water (fatty end) (water soluble end)Case 3: Gases Mixing with Liquids Consider specifically gases in H2O. We know gases dissolve because we hear the fizz from CO2 and we know that fish can breathe O2. But H2O is polar, with hydrogen bonding and according to “like dissolves like” it


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UT CH 302 - Lecture notes

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