cont Trace Element Geochemistry Lecture 24 Review Surfaces in Water Oxygen and metal atoms at an oxide surface are incompletely coordinated hence have partial charge Consequently mineral surfaces immersed in water attract and bind water ID: 926558
Download Presentation The PPT/PDF document "Mineral Surface Reactions" is the property of its rightful owner. Permission is granted to download and print the materials on this web site for personal, non-commercial use only, and to display it on your personal computer provided you do not modify the materials and that you retain all copyright notices contained in the materials. By downloading content from our website, you accept the terms of this agreement.
Slide1
Mineral Surface Reactions(cont.);Trace Element Geochemistry
Lecture 24
Slide2Review: Surfaces in Water
Oxygen
and metal atoms at an oxide surface are incompletely
coordinated hence have partial charge.
Consequently, mineral surfaces immersed in water attract and bind water
molecules. The
water molecules
then
dissociate, leaving a hydroxyl group bound to the surface metal
ions
:
≡
M
+
+ H
2
O ⇄
≡
MOH
+ H
+
Similarly, unbound oxygens react with water to leave a surface hydroxyl group:
≡
O
–
+ H
2
O ⇄
≡
OH
+
OH
–
The surface quickly becomes covered with hydroxyls (
≡
SOH), considered part of the surface rather than the solution.
Slide3Adsorption of Metals and Ligands
Solutes in water can then be adsorbed to the surface as well.
Slide4Development of Surface Charge
Mineral surfaces develop electrical charge for three reasons
:
Complexation reactions between the surface and dissolved
species
Lattice
imperfections
at the solid surface
as well as substitutions within the crystal lattice (e.g., Al3+ for Si4+). Hydrophobic (organic substances)
Slide5Surface ChargeWe define
σ
net
as the
net density of electric charge on the solid
surface (per unit area)
,
and express it as:
σnet = σ0 +
σ
H
+
σ
SC
where
σ
0
is the
intrinsic
surface charge
due to lattice
imperfections, etc.,
σ
H
is the net proton charge
(i.e., the
net of
binding H
+
and OH
–
),
σ
SC
is the charge due to other
surface complexes
.
σ
is usually measured in coulombs per square meter (C/m
2
).
σ
H
is given by:
σ
H
=
F
(Γ
H
-
Γ
OH
)
where
F
is the Faraday constant and
Γ
H
and
Γ
OH
are the adsorption densities (
mol
/m
2
) of H
+
and OH
–
respectively. In a similar way, the charge due to other surface complexes is given by
σ
SC
=
F
(
z
M
Γ
M
+
z
A
Γ
A
)
where the subscripts
M
and
A
refer to metals and anions respectively,
and
z
is the charge of the ion.
Thus
net charge on the mineral surface is:
σ
net
=
σ
0
+
F
(Γ
H
–Γ
OH
+
z
M
Γ
M
+
z
A
Γ
A
)
Slide6Charge as a function of pH
At
some value of pH the surface charge,
σ
net
, will be zero. The pH at which this occurs is known as the isoelectric point,
or
zero point of charge
(ZPC)
. The ZPC is the pH at which the charge on the surface of the solid caused by binding of all ions is 0, which occurs when the charge due to adsorption of cations is balanced by charge due to adsorption of anions.
This depends on the nature of the surface as well as the composition of the solution.
A
related concept is
the
point of zero net proton charge
(
pznpc
)
, which is the point of zero charge when the charge due to the binding of H
+
and OH
–
is 0; that is, pH where
σ
H
=
0 (in pure water).
This is a property of the surface
.
Surface
charge
thus depends
upon the nature of the surface, the nature of the solution, and the ionic strength of the latter
.
ZPC, however does not depend on ionic strength.
Slide7Determining Surface ChargeThe surface charge due to binding of protons and hydroxyls is readily determined by titrating a solution containing a suspension of the material of interest with strong acid or base. The idea is that any deficit in H
+
or OH
–
in the solution is due to binding with the surface.
Slide8Surface PotentialThe charge on a surface exerts a force on ions in the adjacent solution and gives rise to an electric potential,
Ψ
(measured in volts), which
in
turn
depends
upon the nature and distribution of ions in solution, as well as intervening water molecules.
The surface charge,
σ, and potential at the surface, Ψ0, can be related by Gouy-Chapman theory, which is
similar
to Debye–
Hückel
theory.
The relationship between surface charge and the electric potential is:
where
ε
r
is the dielectric constant of water, and ε0 is the permittivity of a vacuum, z is the valence of a symmetrical background electrolyte (e.g., 1 for NaCl, 2 for CaSO4), Ψ0 is the potential at the surface, F is the Faraday constant, T is temperature, R is the gas constant, I is ionic strength of the solution in contact with the surface. Most terms are constants, so at constant temperature, this reduces to: where α and β are constants with values of 0.1174 and 19.5, respectively, at 25˚C.
Slide9Surface Potential as a function of distance
Where the potential is small, the
potential drops off with distance
from the surface
as
:
where
κ
has units of inverse length and is called the Debye length: The one variable, other than temperature, is I.
The inverse
of
κ
is the distance at which the electrostatic potential will decrease by 1/e.
We also see the potential will drop off more rapidly at high ionic strength.
(Atom diameters are ~10
-1
nm)
Slide10Development of the ‘Double Layer’
The surface charge results in an excess concentration of oppositely charged ions
(Na
+
in this example), and
a deficit of like charged
ions (Cl
-
in this example) in the immediately adjacent solution. Thus an electric double layer develops adjacent to the mineral surface.
Slide11The Double Layer
The inner layer,
or Stern Layer
, consists of charges fixed the the surface.
The
outer diffuse layer, or
Gouy
Layer, consists of dissolved ions that retain some freedom of thermal movement
.
The Stern Layer is sometimes further subdivided into an inner layer of specifically adsorbed ions (inner sphere complexes) and an outer layer of ions that retain their solvation shell (outer sphere complexes), called the inner and outer Helmholtz planes respectively.Hydrogens adsorbed to the surface are generally considered to be part of the solid rather than the Stern Layer.The thickness of the Gouy (outer) Layer is considered to be the Debye length, 1/κ and will vary inversely with the square root of ionic strength.
Thus
the
Gouy
Layer will collapse in high ionic strength solutions and expand in low ionic strength ones.
Slide12Importance of the Double Layer
When clays are strongly compacted, the
Gouy
layers of individual particles overlap and ions are virtually excluded from the pore space. This results in retardation of diffusion of ions, but not of water. As a result, clays can act as
semi-permeable membranes
. Because some ions will diffuse more easily than others, a chemical fractionation of the diffusing fluid can result.
At low ionic strength, the charged layer surrounding a particle can be strong enough to repel similar particles with their associated
Gouy
layers. This will prevent particles from approaching closely and hence prevent coagulation. Instead, the particles form a relatively stable
colloidal suspension. As the ionic strength of the solution increases, the Gouy layer is compressed and the repulsion between particles decreases. This allows particles to approach closely enough that they are bound together by attractive van der Waals forces between them. When this happens, they form larger aggregates and settle out of the solution.
For
this reason, clay particles suspended in river water will flocculate and settle out when river water mixes with seawater in an estuary.
Slide13Effect of the surface potential on adsorption
The electrostatic forces also affect complexation reactions at the surface, as we noted at the beginning of this section. An ion must overcome the electrostatic forces associated with the electric double layer before it can participate in surface reactions. We can account for this effect by including it in the Gibbs free energy of
reaction:
∆
G
ads
=
∆
G
intr+∆
G
coul
where
∆G
ads
is the total free energy of the adsorption reaction,
∆
G
int
is the intrinsic free energy of the reaction (i.e., the value the reaction would have in the absence of electrostatic forces; e.g., the same reaction taking place in solution), and ∆Gcoul is the free energy due to the electrostatic forces and is given by:∆Gcoul = F∆ZΨ0where ∆z is the change in molar charge of the surface species due to the adsorption reaction. For example, in the reaction:≡SOH+Pb2+ ⇄ ≡SOPb
+ +H+the value of ∆z is +1 and ∆G
coul =
FΨ0
Slide14Effect on EquilibriumThus if we can calculate ∆
G
coul
, this term can be added to the intrinsic
∆G
for the adsorption reaction (
∆
G
intr
) to obtain the effective value of ∆G (∆Gads). From ∆Gads it is a simple and straightforward matter to calculate Kads:(note equation 6.128 in the book has typos. Should be the above.)Since Kintr = e
-∆
G
intr
/RT
and ∆
G
coul
=
F
∆zΨ0, we have:Thus we need only find the value of Ψ0, which we can calculate from σ.
Slide15Effect of potential on adsorption
The effect of surface potential on a given adsorbate will be to shift the adsorption curves to higher pH for cations and to lower pH for anions.
The figure
illustrates the example of adsorption of Pb on hydrous ferric oxide. When surface potential is considered, adsorption of a given fraction of Pb occurs at roughly 1 pH unit higher than in the case where surface potential is not considered.
In
addition, the adsorption curves become steeper.
Slide16Introduction to Trace Element GeochemistryChapter 7
Slide17ImportanceThough trace elements, by definition, constitute only a small fraction of a system of interest, they provide geochemical and geological information out of proportion to their abundance. There are several reasons for this.
First
,
variations in the concentrations of many trace elements are much larger
than variations in the concentrations of major components, often by many orders of magnitude
.
Second, in any system there are
far more trace elements
than major elements. In most geochemical systems, there are ten or fewer major components that together account for 99% or more of the system. This leaves 80 trace elements. Each element has chemical properties that are to some degree unique, hence there is unique geochemical information contained in the variation of concentration for each element. Thus the 80 trace elements always contain information not available from the variations in the concentrations of major elements. Third, the range in behavior of trace elements is large, and collectively they are sensitive to processes to which major elements are insensitive.
Slide18What is a Trace Element?For most silicate rocks, O, Si, Al, Na, Mg,
Ca
, and Fe are “major elements”.
An operational
definition might be as follows: trace elements are
those elements that are not stoichiometric constituents of phases in the system of interest.
T
his
definition is a bit fuzzy: a trace element in one system is not one in another. For example, K never forms its own phase in mid-ocean ridge basalts (MORB) but K is certainly not a trace element in granites. Of course this definition breaks down for fluid solutions such as water and magma.Trace elements in seawater and in rocks do have one thing in common: neither affect the chemical or physical properties of the system as a whole to a significant extent.
But some components do influence properties even at very low conc.; e.g. trace elements can influence color of minerals.
Perhaps the best definition
of a trace element is:
an element whose activity obeys Henry’s Law in the system of interes
t.
This
implies sufficiently dilute concentrations that, for trace element A and major component B, A–A interactions are not significant compared to A–B interactions, simply because A–A interactions will be rare.
Slide19Concentrations in the Silicate Earth
Slide20Goldschmidt’s Classification
Atmophile
elements are generally extremely volatile (i.e., they form gases or liquids at the surface of the Earth) and are concentrated in the atmosphere and hydrosphere.
Lithophile
, siderophile and chalcophile refer to the tendency of the element to partition into a silicate, metal, or sulfide
liquid
respectively.
Goldschmidt classified them based on the minerals in which they were concentrated in meteorites.
Lithophile elements are those showing an affinity for silicate phases and are concentrated in the silicate portion (crust and mantle) of the Earth. Siderophile elements have an affinity for a metallic liquid phase. Concentrated in Earth’s core.
Chalcophile
elements have an affinity for a sulfide liquid phase. They are also depleted in the silicate earth and may be concentrated in the core
.
Most
elements that are siderophile are usually also somewhat chalcophile and vice versa
.
Slide21Goldschmidt’s Classification
Slide22Distribution of the Elements
Atmophile
in the atmosphere.
Siderophile
(and most
chalcophile
elements) in the core.
Lithophile
in the mantle and crust.Incompatible elements, those not accepted in mantle minerals, are concentrated in the crust.Compatible elements concentration in the mantle.
Slide23Geochemical Classification
Slide24Geochemical ClassificationThe volatile elements: Noble gases, nitrogen
The semi-
volatiles
they partition readily into a fluid or gas phase (e.g.,
Cl
, Br) or form compounds that are volatile (e.g., SO
2
, CO
2
). Not all are volatile in a strict sense (volatile in a strict sense means having a high vapor pressure or low boiling point; indeed, carbon is highly refractory in the elemental form). The alkali and alkaline earth elementsThe alkali and alkaline earth elements have a single valence state (+1 for the alkalis, +2 for the alkaline earths). The bonds these elements form are strongly ionic in character (Be is an exception, as it forms bonds with a more covalent character)These elements relatively soluble in aqueous
solution.
T
he
atoms of these elements behave approximately as hard
charged spheres; size and charge dictate their behavior in igneous processes.
The heavier alkalis and alkaline earths have ionic radii too large to fit in many minerals (mantle ones in particular). As a consequence, they are said to be
incompatible
.
H
igh field strength (HFS) elementsSo called because of their high ionic charge: Zr and Hf have +4 valence states and Ta and Nb have +5 valence states. Th (+4) and U (+4, +6) are sometimes included in this group. Because of their high charge, all are relatively small cations but because of their high charge they are excluded from most minerals and hence are also incompatible.The first series transition metals Chemistry is considerably more complex: many of the transition elements have two or more valence states; covalent bonding is more important (bonding with oxygen in oxides and silicates is predominantly ionic, but bonding with other non-metals, such as sulfur, can be largely covalent) A final complicating factor is the geometry of the d-orbitals, which are highly directional and thus bestow upon the transition metals specific preferences for the geometry of coordinating ligands. They range from moderately incompatible (e.g., Ti, Cu, Zn) to very compatible (e.g., Cr, Ni, Co) .The noble metalsThe platinum group elements (Rh, Ru, Pd,
Os, Ir, Pt) plus gold (and Re) are often collectively called the noble metals. These metals are so called for two reasons: first, they are rare, and second, they are unreactive and quite stable in metallic form. Their rarity is in part a consequence of their highly
siderophilic character. These elements are all also to varying degrees. These elements exist in multiple valence states, ranging from 0 to +8, and have bonding behavior influenced by the
d-orbitals.Au Pt, Re, and Pd are moderately incompatible elements, while Rh. Ru
, Os, and Ir are highly compatible
Slide25The Lanthanide Rare Earths
Rare earths have become critical to the 21
st
century society: electronics, displays, electric motors, turbines, fiber optics, etc..
Slide26The Rare Earth Elements
The
rare earths and Y are strongly
electropositive.
As a result, they form predominantly ionic bonds, and
behave as
hard charged
spheres.
The
lanthanide rare earths are in the +3 valence state over a wide range of oxygen fugacities.In the transition metals, the s orbital of the outermost shell is filled before filling of lower electron shells is complete so the configuration of the valence electrons is similar in all the rare earth, hence all exhibit similar chemical behavior.
Easily Give
up electrons
Slide27The Rare Earth Elements
Ionic radius, which decreases
progressively from
La
3
to
Lu
3+
(93 pm
) governs their relative behavior. Because of their high charge and large radii, the rare earths are incompatible elements. The degree of
incompatibility of the lanthanides varies with atomic number.
Highly charged U and
Th
are highly incompatible elements, as are the lightest rare earths
.
However, the heavy rare earths have sufficiently small radii that they can be accommodated to some degree in many common
minerals such as Lu for Al in garnet.
Eu2+ can substitute for Ca in plagioclase.
Slide28Rare Earth Diagrams
The systematic variation in
lathanide
rare earth behavior is best illustrated by plotting the log of the
relative abundances
as a function of
atomic.
Relative abundances are calculated by dividing the concentration of each rare earth by its concentration in a set of normalizing values, such as the concentrations of rare earths in chondritic
meteorites.
Rare earths are also refractory elements, so that their relative abundances are the same in most primitive meteorites - and presumably (to a first approximation) in the Earth.Why do we use relative abundances? The abundances of even-numbered elements in the
solar system are
greater than those of neighboring odd-numbered
elements and abundances
generally decrease with increasing atomic
number, leading to a saw-toothed abundance pattern. Normalizing eliminates this.
Abundances in chondritic meteorites are generally used for normalization. However, other normalizations are possible: sediments (and waters) are often normalized to average shale.