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Activity

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Anion is surrounded by cations ... more anions in solution increased ionic atmosphere decreases the attraction ... between any particular cation and anion ... – PowerPoint PPT presentation

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Title: Activity


1
Chapter 8
  • Activity

2
Assumptions Thus Far
  • Equilibrium Constants
  • Assumes Naked Ions
  • Assumes that the Ionic Strength is controlled by
    the ions of interest ONLY being in solution

3
Naked Ions
  • The true radius of the ion in solution is the
    hydrated radius
  • Hydrated radius - The effective size of an ion or
    a molecule plus its associated water molecules in
    solution
  • larger radius of naked ion ? more diffuse
    electric charge ? fewer water molecules
    surrounding the ion
  • greater ion charge ? increased solvent attaction
    ? greater the hydrated radius
  • Effect of Ion Sheath - decreases the frequency in
    which molecules of interest will interact.

4
Ionic Strength
  • The truth is that the counter ions from the
    original reactants also exist.
  • Hg2(NO3)2 2KIO3 ? Hg2(IO3)2 2K 2NO3-
  • Introduction of an inert salt to a sparingly
    soluble salt increases the solubility of the
    sparingly soluble salt
  • Introduction of the inert salt increases the
    ionic strength of the solution

5
Ionic Strength
  • Increased Solubility
  • Anion is surrounded by cations
  • more cations in solution ? increased ionic
    atmosphere ? decreases the attraction between any
    particular sets of ions ? the less tendency for
    the ions to interact
  • Cation is surrounded by anions
  • more anions in solution ? increased ionic
    atmosphere ? decreases the attraction between any
    particular sets of ions ? the less tendency for
    the ions to interact

6
Terminology
  • Ionic Atmosphere - The region of solution around
    an ion or a charged particle. It contains an
    excess of oppositely charged ions.
  • The greater the ionic strength of a solution, the
    higher the charge in the ionic atmosphere.
  • Each ion-plus-atmosphere contains less net charge
    and there is less attraction between any
    particular cation and anion

7
Terminology
  • Ionic Strength (?) - a measure of the total
    concentration of ions in solution.
  • ? ½?icizi2
  • ci - is the concentration of the ith ion in
    solution
  • zi - the charge on that ion

8
Ionic Strength Example
  • Find the ionic strength of
  • (a) 0.10 M NaNO3
  • (b) 0.010 M Na2SO4 and
  • (c) 0.020 M KBr plus 0.010 M Na2SO4

9
Activity Coefficients
  • Equilibrium Constant (K) as previously written,
    does not predict the effect of ionic strength on
    a chemical reaction.
  • To take into account the effect of the ionic
    strength, concentrations are replaced by
    activities
  • Ac C?c
  • K (AccAdd) / (AaaAbb)

10
Activity Coefficients
  • Therefore
  • K (C?CcD ?Dd) / (A?AaB ?Bb)
  • Activity Coefficient determined by the Extended
    Debye-Hückel equation
  • log ? (-0.51z2??) / (1 (??? / 305))
  • ? - size of the hydrated ion in picometers

11
Activity Coefficients
  • Table 8-1 lists sizes and activity coefficients
    of various ions
  • Note All ions of the same size, charge, and of
    the same concentration have the same activity
    coefficient.

12
Ionic Strength, Ion Charge, and Ion Size effect
  • Increased ionic concentration ? decreased
    activity coefficient
  • Low ionic strengths ? activity coefficients
    approach unity
  • Increased ion charge () ? increased departure of
    activity coefficient from unity
  • corrections are more important where the charge
    of the ion is 3 compared to 1
  • Smaller hydrated radius ? increased importance of
    activity effects

13
Activity Coefficient Calculation
  • Find the activity coefficient of Hg22 in a
    solution of 3.3 mM Hg2(NO3)2.
  • Find the activity coefficient of each ion at the
    indicated ionic strength
  • (a) S2- (? 0.001 M) (b) PO43- (? 0.001 M)
  • (c) Sn4 (? 0.05 M) (d) H2NCH2CO2- ? 0.01 M)

14
Interpolation
  • Table 8-1
  • Gives ionic strengths for ions at various
    concentrations
  • Missing values can be extrapolated using linear
    interpolation
  • (unknown y interval / ?y) (known x interval /
    ?x)

15
Interpolation
  • Calculate the activity coefficient of H when ?
    0.025
  • Calculate the activity coefficient of OH- when ?
    0.030 M.
  • Calculate the activity coefficient of formate,
    HCO2-, when ? 0.038 M by using
  • (a) the extended Debye-Huckel Eqn
  • (b) linear interpolation

16
Using Activity Coefficients
  • Write each equilibrium constant with activities
    in place of concentrations
  • Use the ionic strength of the solution to find
    the activity coefficients

17
Using Activity Coefficients
  • Solubility Problem
  • What is the Ca2 concentration in a solution of
    0.05 M NaClO4 that is saturated with CaF2?
  • The Common Ion Effect
  • Find the concentration of Ca2 in 0.050 M NaF
    saturated with CaF2.

18
Using Activity Coefficients
  • Calculate the solubility of Ag2CrO4 (expressed as
    moles of CrO42- per liter) in
  • (a) 0.050 M KClO4 (b) 0.0050 M AgNO3

19
Using Activity Coefficients
  • Problem Requiring an Iterative Solution
  • Calculate the solubility of LiF in distilled
    water.
  • Calculate the concentration of Tl in a saturated
    solution of TlBr in water.

20
pH Revisited
  • Again concentration is replaced with activity
  • pH -log AH -log H?H

21
pH Revisited
  • Calculate the pH of pure water using activity
    coefficients correctly.
  • Calculate the pH of water containing 0.10 M KCl
    at 25oC.
  • Find the pH of (a) 0.050 M HClO4 and (b) 0.050 M
    HClO4 plus 0.050 M HBr

22
Chapter 8 - Homework
  • Problems - 3, 5, 7, 8, 12, 13, 19
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