IS SOLUBILITY THE ONLY CONTROL ON SOLUTE CONCENTRATIONS? - PowerPoint PPT Presentation

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IS SOLUBILITY THE ONLY CONTROL ON SOLUTE CONCENTRATIONS?

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Title: IS SOLUBILITY THE ONLY CONTROL ON SOLUTE CONCENTRATIONS?


1
IS SOLUBILITY THE ONLY CONTROL ON SOLUTE
CONCENTRATIONS?
  • The answer is NO! Solubility often controls the
    concentrations of major solutes such as Si, Ca,
    and Mg, and some minor or trace solutes such as
    Al and Fe.
  • However, for many trace elements, sorption
    processes maintain concentrations below
    saturation with respect to minerals.
  • In other words, sorption is a means to remove
    solutes even when the solution is undersaturated
    with any relevant solids.

2
Mineral Surfaces
  • Minerals which are precipitated can also interact
    with other molecules and ions at the surface
  • Attraction between a particular mineral surface
    and an ion or molecule due to
  • Electrostatic interaction (unlike charges
    attract)
  • Hydrophobic/hydrophilic interactions
  • Specific bonding reactions at the surface

3
DEFINITIONS
  • Sorption - removal of solutes from solution onto
    mineral surfaces.
  • Sorbate - the species removed from solution.
  • Sorbent - the solid onto which solution species
    are sorbed.
  • Three types of sorption
  • Adsorption - solutes held at the mineral surface
    as a hydrated species.
  • Absorption - solute incorporated into the mineral
    structure at the surface.
  • Ion exchange - when an ion becomes sorbed to a
    surface by changing places with a similarly
    charged ion previously residing on the sorbent.

4
Charged Surfaces
  • Mineral surface has exposed ions that have an
    unsatisfied bond ? in water, they bond to H2O,
    many of which rearrange and shed a H
  • S- H2O ? SH2O ? S-OH H

OH
OH
OH2
H
OH
OH
OH
H
OH
5
Surfaces as acid-base reactants
  • The surface SITE acts as an amphoteric
    substance ? it can take on an extra H or lose
    the one it has to develop charge
  • S-O- H ? S-OH ? S-OH2
  • The of sites on a surface that are , -, or 0
    charge is a function of pH
  • pHzpc is the pH where the sites - sites 0
    sites and the surface charge is nil

OH
OH2
O-
OH
O-
OH
OH2
6
GOUY-CHAPMAN DOUBLE-LAYER MODEL
STERN-GRAHAME TRIPLE-LAYER MODEL
7
Sorption to S-OH sites
  • S-OH M2 ? S-OM H
  • S-OH L2- ? S-L- OH-
  • In addition, can also have bi-dendate sorption
    reactions

8
pHzpc
  • Zero Point of Charge, A.k.a Zero Point of Net
    Proton Charge (pHZPNPC) or the Isoelectric Point
    (IEP)
  • Measured by titration curves (pHzpc similar to
    pKa) or electrophoretic mobility (tendency of
    the solids to migrate towards a positively
    charged plate)
  • Below pHzpc ? more sites are protonated ? net
    charge
  • Above pHzpc ? more sites are unprotonated ? net -
    charge

9
POINT OF ZERO CHARGE CAUSED BY BINDING OR
DISSOCIATION OF PROTONS
10
From Stumm and Morgan, Aquatic Chemistry
11
Anion-Cation sorption
  • Equilibrium description for sorption of
  • S-OH M2 ? S-OM H
  • Where Dz is the stoichiometric net change in
    surface charge due to the sorption reaction (1
    here), F is Faradays constant (96485 Coulombs
    per mole), ? is the electrical potential at the
    surface, R is the gas constant, and T is
    temperature in Kelvins, the whole right term is
    called the coulombic term

12
Inner Sphere and Outer Sphere
  • Outer Sphere surface complex ? ion remains
    bounded to the hydration shell so it does not
    bind directly to the surface, attraction is
    purely electrostatic
  • Inner Sphere surface complex ? ion bonds to a
    specific site on the surface, this ignores
    overall electrostatic interaction with bulk
    surface (i.e. a cation could bind to a mineral
    below the mineral pHzpc)

13
ADSORPTION OF METAL CATIONS - I
  • In a natural solution, many metal cations compete
    for the available sorption sites.
  • Experiments show some metals have greater
    adsorption affinities than others. What factors
    determine this selectivity?
  • Ionic potential defined as the charge over the
    radius (Z/r).
  • Cations with low Z/r release their waters of
    hydration more easily and can form inner-sphere
    surface complexes.

14
ADSORPTION OF METAL CATIONS - II
  • Many isovalent series cations exhibit decreasing
    sorption affinity with decreasing ionic radius
  • Cs gt Rb gt K gt Na gt Li
  • Ba2 gt Sr2 gt Ca2 gt Mg2
  • Hg2 gt Cd2 gt Zn2
  • For transition metals, electron configuration
    becomes more important than ionic radius
  • Cu2 gt Ni2 gt Co2 gt Fe2 gt Mn2

15
ADSORPTION OF METAL CATIONS - III
  • For variable-charge sorbents, the fraction of
    cations sorbed increases with increasing pH.
  • For each individual ion, the degree of sorption
    increases rapidly over a narrow pH range (the
    adsorption edge).

16
SORPTION ISOTHERMS - I
  • The capacity for a soil or mineral to adsorb a
    solute from solution can be determined by an
    experiment called a batch test.
  • In a batch test, a known mass of solid (S m) is
    mixed and allowed to equilibrate with a known
    volume of solution (V ) containing a known
    initial concentration of a solute (C i). The
    solid and solution are then separated and the
    concentration (C ) of the solute remaining is
    measured. The difference C i - C is the
    concentration of solute adsorbed.

17
SORPTION ISOTHERMS - II
  • The mass of solute adsorbed per mass of dry solid
    is given by
  • where S m is the mass of the solid.
  • The test is repeated at constant temperature but
    varying values of C i. A relationship between C
    and S can be graphed. Such a graph is known as an
    isotherm and is usually non-linear.
  • Two common equations describing isotherms are the
    Freundlich and Langmuir isotherms.

18
FREUNDLICH ISOTHERM
  • The Freundlich isotherm is described by
  • where K is the partition coefficient and n ? 1.

When n lt 1, the plot is concave with respect to
the C axis. When n 1, the plot is linear. In
this case, K is called the distribution
coefficient (Kd ).
19
LANGMUIR ISOTHERM
  • The Langmuir isotherm describes the situation
    where the number of sorption sites is limited, so
    a maximum sorptive capacity (S max) is reached.

The governing equation for Langmuir isotherms is
20
ION EXCHANGE REACTIONS
  • Ions adsorbed by outer-sphere complexation and
    diffuse-ion adsorption are readily exchangeable
    with similar ions in solution.
  • Cation exchange capacity The concentration of
    ions, in meq/100 g soil, that can be displaced
    from the soil by ions in solution.

21
ION EXCHANGE REACTIONS
  • Exchange reactions involving common, major
    cations are treated as equilibrium processes.
  • The general form of a cation exchange reaction
    is
  • nAm mBX ? mBn nAX
  • The equilibrium constant for this reaction is
    given by

22
Sorption of organic contaminants
  • Organic contaminants in water are often sorbed to
    the solid organic fractions present in soils and
    sediments
  • Natural dissolved organics (primarily humic and
    fulvic acids) are ionic and have a Koc close to
    zero
  • Solubility is correlated to Koc for most organics

23
Measuring organic sorption properties
  • Kow, the octanol-water partition coefficient is
    measured in batches with ½ water and ½ octanol
    measures proportion of added organic which
    partitions to the hydrophobic organic material
  • Empirical relation back to Koc
  • log Koc 1.377 0.544 log Kow
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