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ACTIVITY. Activity Coefficients. No direct way to measure the effect of a single ion in solution (charge balance) Mean Ion Activity Coefficients – determined for a salt (KCl, MgSO 4 , etc.) g ±KCl = [( g K )( g Cl )] 1/2 K sp = g ±KCl 2 (mK + )(mCl - )
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Activity Coefficients • No direct way to measure the effect of a single ion in solution (charge balance) • Mean Ion Activity Coefficients – determined for a salt (KCl, MgSO4, etc.) g±KCl = [(gK)(gCl)]1/2 Ksp= g±KCl2(mK+)(mCl-) • MacInnes Convention gK = gCl= g±KCl • Measure other salts in KCl electrolyte and substitute g±KCl in for one ion to measure the other ion w.r.t. g±KCl and g±salt
Debye-Hückel • Assumes ions interact coulombically, ion size does not vary with ionic strength, and ions of same sign do not interact • A, B often presented as a constant, but: A=1.824928x106r01/2(T)-3/2, B=50.3 (T)-1/2 Where is the dielectric constant of water and r is the density
Higher Ionic Strengths • Activity coefficients decrease to minimal values around 1 - 10 m, then increase • the fraction of water molecules surrounding ions in hydration spheres becomes significant • Activity and dielectric constant of water decreases in a 5 M NaCl solution, ~1/2 of the H2O is complexed, decreasing the activity to 0.8 • Ion pairing increases, increasing the activity effects
Extended Debye-Hückel • Adds a correction term to account for increase of gi after certain ionic strength • Truesdell-Jones (proposed by Huckel in 1925) is similar:
Davies Equation • Lacks ion size parameter –only really accurate for monovalent ions • Often used for Ocean waters, working range up to 0.7 M (avg ocean water I)
Specific Ion Interaction theory • Ion and electrolyte-specific approach for activity coefficients • Where z is charge, i, m(j) is the molality of major electrolyte ion j (of opposite charge to i). Interaction parameters, (i,j,I) describes interaction of ion and electrolyte ion • Limited data for these interactions and assumes there is no interaction with neutral species
Pitzer Model • At ionic strengths above 2-3.5, get +/+, -/- and ternary complexes • Terms above describe binary term, fy describes interaction between same or opposite sign, terms to do this are called binary virial coefficients • Ternary terms and virial coefficients refine this for the activity coefficient
Setchenow Equation log gi=KiI • For molecular species (uncharged) such as dissolved gases, weak acids, and organic species • Ki is determined for a number of important molecules, generally they are low, below 0.2 activity coefficients are higher, meaning mi values must decline if a reaction is at equilibrium “salting out” effect
Half Reactions • Often split redox reactions in two: • oxidation half rxn e- leaves left, goes right • Fe2+ Fe3+ + e- • Reduction half rxn e- leaves left, goes right • O2 + 4 e- 2 H2O • SUM of the half reactions yields the total redox reaction 4 Fe2+ 4 Fe3+ + 4 e- O2 + 4 e- 2 H2O 4 Fe2+ + O2 4 Fe3+ + 2 H2O
ELECTRON ACTIVITY • Although no free electrons exist in solution, it is useful to define a quantity called the electron activity: • The pe indicates the tendency of a solution to donate or accept a proton. • If pe is low, there is a strong tendency for the solution to donate protons - the solution is reducing. • If pe is high, there is a strong tendency for the solution to accept protons - the solution is oxidizing.
THE pe OF A HALF REACTION - I Consider the half reaction MnO2(s) + 4H+ + 2e- Mn2+ + 2H2O(l) The equilibrium constant is Solving for the electron activity
DEFINITION OF Eh Eh - the potential of a solution relative to the SHE. Both pe and Eh measure essentially the same thing. They may be converted via the relationship: Where = 96.42 kJ volt-1 eq-1 (Faraday’s constant). At 25°C, this becomes or
Free Energy and Electropotential • Talked about electropotential (aka emf, Eh) driving force for e- transfer • How does this relate to driving force for any reaction defined by DGr ?? DGr = - nE • Where n is the # of e-’s in the rxn, is Faraday’s constant (23.06 cal V-1), and E is electropotential (V) • pe for an electron transfer between a redox couple analagous to pK between conjugate acid-base pair
Nernst Equation Consider the half reaction: NO3- + 10H+ + 8e- NH4+ + 3H2O(l) We can calculate the Eh if the activities of H+, NO3-, and NH4+ are known. The general Nernst equation is The Nernst equation for this reaction at 25°C is
Let’s assume that the concentrations of NO3- and NH4+ have been measured to be 10-5 M and 310-7 M, respectively, and pH = 5. What are the Eh and pe of this water? First, we must make use of the relationship For the reaction of interest rG° = 3(-237.1) + (-79.4) - (-110.8) = -679.9 kJ mol-1
O2/H2O C2HO
UPPER STABILITY LIMIT OF WATER (Eh-pH) To determine the upper limit on an Eh-pH diagram, we start with the same reaction 1/2O2(g) + 2e- + 2H+ H2O but now we employ the Nernst eq.
As for the pe-pH diagram, we assume that pO2 = 1 atm. This results in This yields a line with slope of -0.0592.
LOWER STABILITY LIMIT OF WATER (Eh-pH) Starting with H+ + e- 1/2H2(g) we write the Nernst equation We set pH2 = 1 atm. Also, Gr° = 0, so E0 = 0. Thus, we have
Construction of these diagrams • For selected reactions: Fe2+ + 2 H2O FeOOH + e- + 3 H+ How would we describe this reaction on a 2-D diagram? What would we need to define or assume?
How about: • Fe3+ + 2 H2O FeOOH(ferrihydrite) + 3 H+ Ksp=[H+]3/[Fe3+] log K=3 pH – log[Fe3+] How would one put this on an Eh-pH diagram, could it go into any other type of diagram (what other factors affect this equilibrium description???)
INCONGRUENT DISSOLUTION • Aluminosilicate minerals usually dissolve incongruently, e.g., 2KAlSi3O8 + 2H+ + 9H2O Al2Si2O5(OH)4 + 2K+ + 4H4SiO40 • As a result of these factors, relations among solutions and aluminosilicate minerals are often depicted graphically on a type of mineral stability diagram called an activity diagram.
ACTIVITY DIAGRAMS: THE K2O-Al2O3-SiO2-H2O SYSTEM We will now calculate an activity diagram for the following phases: gibbsite {Al(OH)3}, kaolinite {Al2Si2O5(OH)4}, pyrophyllite {Al2Si4O10(OH)2}, muscovite {KAl3Si3O10(OH)2}, and K-feldspar {KAlSi3O8}. The axes will be aK+/aH+ vs. aH4SiO40. The diagram is divided up into fields where only one of the above phases is stable, separated by straight line boundaries.
Activity diagram showing the stability relationships among some minerals in the system K2O-Al2O3-SiO2-H2O at 25°C. The dashed lines represent saturation with respect to quartz and amorphous silica.