Post on 24-Dec-2015
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Dissolved Inorganic Carbon (DIC)• Initially, DIC in groundwater comes from CO2
– CO2(g) + H2O ↔ H2CO3°
– PCO2: partial pressure (in atm)
– PCO2 of soil gas can be 10-100 times the PCO2 of atmosphere
• In groundwater, CO2 usually increases along a flow path due to biodegradation in a closed system– CH2O + O2 CO2 + H2O
• CH2O = “generic” organic matter
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Dissolved Inorganic Carbon (DIC)
• Equilibrium expression with a gas is known as Henry’s Law:
• CO2 + H2O H2CO3; KCO2 = 10-1.47
• H2CO3 HCO3- + H+; Ka1 = 10-6.35
• HCO3- CO3
2- + H+; Ka2 = 10-10.33
4Walt Tue Feb 21 2006
2 3 4 5 6 7 8 9 10 11 12–16
–14
–12
–10
–8
–6
–4
–2
0
pH
Sp
eci
es
with
HC
O3- (
log
mo
lal)
CO2(aq) CO
3--
HCO3-
Total DIC = 10-1 M
pH = 6.35 pH = 10.33
Common pH rangein natural waters
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Alkalinity
• Alkalinity = acid neutralizing capability (ANC) of water– Total effect of all bases in solution– Typically assumed to be directly correlated to
HCO3- concentration in groundwater
– HCO3- = alkalinity
0.82
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Salts (Electrolytes)
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Salts
• When you mix an acid + base, H+ and OH- form H2O• The remaining anion and cation can form a salt
– e.g., mix H2SO4 + CaOH, make CaSO4
– mix HCl + NaOH, make NaCl
• Salts are named after the acid they come from– e.g., chlorides, carbonates, sulfates, etc.
• All minerals are salts except oxides, hydroxides, and native elements
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Solubility of Salts• Remember: A saturated solution of a salt is in a
state of equilibrium• Al2(SO4)3(s) 2Al3+ + 3SO4
2-
– Can write our familiar equilibrium expression with an equilibrium constant
– Ksp = ([Al3+]2)([SO42-]3)
• Ksp = solubility product constant• Activities of solids = 1 by definition• Ksp values can be calculated (or looked up)
– Ksp for Al2(SO4)3(s) = 69.19 (at 25°C)• Very large Ksp which means the salt is very soluble
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Solubility• Al2(SO4)3(s) 2Al3+ + 3SO4
2-
– What is the solubility of Al2(SO4)3?• What are the activities of Al3+ and SO4
2- in a saturated solution of Al2(SO4)3?
– – Thus in a saturated solution of Al2(SO4)3
• [Al3+] = 2x = 1.829 mol/L• [SO4
2-] = 3x = 2.744 mol/L– Solubility of Al2(SO4)3 = 0.915 x the molecular
weight (342.148 g/mol) = 3.13 x 102 g/L
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Solubility
• We often want to know whether a solution is saturated with respect to a mineral
• e.g., Is a solution with 5 x 10-2 mol/L Ca2+ and 7 x 10-3 mol/L SO4
2- saturated with respect to gypsum (CaSO42H2O)?
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Gypsum Solubility
• CaSO4 2H2O Ca2+ + SO42-
– Ksp = [Ca2+] [SO42-] = 10-4.6
– If the solution is saturated, the product of the activities would = 10-4.6
– (Note that [Ca2+] and [SO42-] don’t have to be equal)
– (Ca2+)(SO42-) = (5x10-2)(7x10-3) = IAP = 10-3.45
– SI = -3.45 – (-4.6) = 1.15– Because SI > 0, gypsum predicted to precipitate
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How much gypsum would precipitate to reach equilibrium (saturation)?
• CaSO42H2O Ca2+ + SO42- + 2H2O
– Ksp = [Ca2+] [SO42-] = 10-4.6
– As gypsum precipitates (reverse reaction), the IAP will decrease because [Ca2+] and [SO4
2-] are being used up
– Once the IAP = Ksp, the solution will be in equilibrium with respect to gypsum
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How much gypsum would precipitate to reach equilibrium (saturation)?
• CaSO42H2O Ca2+ + SO42- + 2H2O
– Ksp = [Ca2+] [SO42-] = 10-4.6
– The solution initially has 5x10-2 mol/L Ca2+ and 7x10-3 mol/L SO4
2- – To reach equilibrium, x moles precipitate:
• [Ca2+] = 5x10-2 - x; [SO42-] = 7x10-3 - x;
• Substitute into eq. above: [5x10-2 - x] [7x10-3 - x] = 10-4.6 • Eventually get x = 6.45 x 10-3
– Amount of gypsum that will precipitate in this solution is 6.45 x 10-3 x 172.17 (mc. wt.) = 1.11 g/L
• At this point, IAP = Ksp and the solution is saturated with respect to gypsum, and no more will precipitate
• Equilibrium has been reached
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Changing solution composition due to precipitation of gypsum
• As gypsum precipitates, the [Ca2+] / [SO42-]
ratio increases from 7.1 to 79.2– The precipitation of a salt reduces the
concentrations of ions and changes the chemical composition of remaining solution
– In our example, if precipitation continues, [SO42-]
will be used up, and none will remain in solution
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Ca2+
SO42-
Ca2+
SO42-
= 7.1
= 79.2
(Equilibrium reached)
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Geochemical Divide
• The initial ratio of species can affect which minerals precipitate
• GEOCHEMICAL DIVIDE– If [Ca2+] / [SO4
2-] had been < 1 instead of > 1, then [SO4
2-] would have become concentrated relative to [Ca2+]
– End up with a different final solution– May lead to precipitation of different minerals– This is important during the evolution of brines by
evaporative concentration
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Precipitation of Salts in Natural Waters
• Natural waters are complex, may have more than 1 salt precipitating
• Let’s consider 2 sulfate minerals, gypsum and barite– CaSO42H2O Ca2+ + SO4
2- + 2H2O• Ksp (gypsum) = [Ca2+] [SO4
2-] = 10-4.6
– BaSO4 Ba2+ + SO42-
• Ksp (barite) = [Ba2+] [SO42-] = 10-10.0
– Barite is much less soluble than gypsum
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Precipitation of Salts in Natural Waters
• [SO42-] has the same value in both equilibria:
– [Ba2+] 10-4.6 / [Ca2+] = 10-10.0
– [Ba2+] / [Ca2+] = 10-5.4 – [Ca2+] is 250,000 x [Ba2+] when the solution is
saturated with respect to both minerals
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Gypsum and Barite equilibrium
• [SO42-] has the same value in both equilibria:
– [Ba2+] 10-4.6 / [Ca2+] = 10-10.0
– [Ba2+] / [Ca2+] = 10-5.4 – [Ca2+] is 250,000 x [Ba2+] when the solution is
saturated with respect to both minerals• Solve for [SO4
2-] using simultaneous equations– [SO4
2-]2 = 10-4.6 + 10-10.0
– [SO42-] = 10-2.3 mol/L
– Note that barite only contributes a negligible amount of [SO4
2-]
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Gypsum and Barite equilibrium
• Suppose a saturated solution of barite comes into contact with gypsum – It is likely that the solution is undersaturated with
respect to gypsum, which is much more soluble than barite
– If gypsum dissolves, [SO42-] will increase
• CaSO42H2O Ca2+ + SO42- + 2H2O
– The increase in [SO42-] can cause the solution to
become supersaturated with respect to barite, which is less soluble than gypsum
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Gypsum and Barite equilibrium• CaSO42H2O Ca2+ + SO4
2- + 2H2O
• Ba2+ + SO42- BaSO4
– Barite precipitates as gypsum dissolves until [Ca2+] / [Ba2+] approaches 250,000
• Then replacement of gypsum by barite stops because solution is saturated with respect to both minerals
– This is called the common ion effect
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Precipitation of Salts in Natural Waters
• Replacement of 1 mineral by another is common in geology– Introduction of a common ion causes solution to
become supersaturated with respect to the less soluble compound
– Thus the more soluble compound is always replaced by less soluble
– Makes sense: less soluble happier as solid, more soluble happier dissolved (relatively)
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Supersaturation
• Solutions in nature become supersaturated with respect to a mineral by:
– Introduction of a common ion– Change in pH– Evaporative concentration– Temperature variations
• In general solubilities increase with increasing T, but not always (e.g., CaCO3)
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Calcite Solubility
• CaCO3 Ca2+ + CO32-; Ksp = 10-8.35 (1)
• HCO3- CO3
2- + H+; Ka2 = 10-10.33 (2)
• H2CO3 HCO3- + H+; KH2 = 10-6.35 (3)
• CO2(g) + H2O H2CO3; K = 10-1.47 (4)– If open to atmosphere
• H2O H+ + OH- (5)• 7 ions/molecules, need 2 more equations or to fix
something (make constant)
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Calcite Solubility• Fix PCO2 at 10-3.5 atm
• (4) [H2CO3] = 10-1.47 x 10-3.5 = 10-4.97
– [H2CO3] = 1.07 x 10-5 mol/L
• (6) charge balance:– 2(Ca2+) + (H+) = 2(CO3
2-) + (HCO3-) + (OH-)
• Now have 6 equations and 6 unknowns
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Calcite Solubility• After some algebra:• (Ca2+) = 5.01 x 10-4 mol/L (20.1 mg/L)• Solubility (S) of calcite = 5.01 x 10-4 x 100.0787
(MW) = 5.01 x 10-2 g/L– For calcite in water in equilibrium with CO2, at 25°C– pH = 8.30
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0 2 4 6 8 10 12 14–10
–8
–6
–4
–2
0
pH
log
a C
a++
HCO3-
CO2(aq)
CO3--
Calcite
25°C
Walt Tue Feb 21 2006
Dia
gram
HC
O3- ,
T
=
25 °
C ,
P
=
1.01
3 ba
rs,
a [m
ain]
=
10
–3,
a [H
2O
] =
1;
Sup
pres
sed:
CaH
CO
3+
H2CO3
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Calcite Solubility• The reaction we just used for calcite
dissolution generally doesn’t occur in nature– CaCO3 Ca2+ + CO3
2-
• Dissolution of calcite done primarily by acid– In natural systems, primary acid is– CaCO3 + H2CO3 Ca2+ + 2HCO3
-
CO2
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Calcite Solubility• Let us consider CaCO3 solubility as affected by
variations in PCO2, pH, and T– CO2(g) CO2(aq)
– CO2(aq) + H2O H2CO3
– CaCO3 + H2CO3 Ca2+ + 2HCO3-
• Predict changes in solubility from these reactions
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Calcite Solubility• CO2(g) CO2(aq)
• CO2(aq) + H2O H2CO3
• CaCO3 + H2CO3 Ca2+ + 2HCO3-
• Increase PCO2?– Increases (H2CO3), which increases amount of CaCO3
dissolved (at constant T)• Decreasing PCO2?
– Decreases (H2CO3), causes saturated solution to become supersaturated and precipitate CaCO3 until equilibrium restored
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CaCO3 + H2CO3 Ca2+ + 2HCO3-
At Saturation
~25 mg/L calcite could be precipitated
●
●
What if we increase PCO2 from atmospheric by 10x?
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Calcite Solubility• Why does the pH decrease as PCO2 increases?
– CO2(g) CO2(aq)
– CO2(aq) + H2O H2CO3
– CaCO3 + H2CO3 Ca2+ + 2HCO3-
• Increasing PCO2 increases H2CO3, which dissociates:– H2CO3 HCO3
- + H+
– Increasing H+ in solution decreases pH– And what happens to calcite as we decrease pH?
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0 2 4 6 8 10 12 14–10
–8
–6
–4
–2
0
pH
log
a C
a++
HCO3-
CO2(aq)
CO3--
Calcite
25°C
Walt Tue Feb 21 2006
Dia
gram
HC
O3- ,
T
=
25 °
C ,
P
=
1.01
3 ba
rs,
a [m
ain]
=
10
–3,
a [H
2O
] =
1;
Sup
pres
sed:
CaH
CO
3+
H2CO3
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0 2 4 6 8 10 12 14–10
–8
–6
–4
–2
0
pH
log
a C
a++
HCO3-
CO2(aq)
CO3--
Calcite
25°C
Walt Tue Feb 21 2006
Dia
gram
HC
O3- ,
T
=
25 °
C ,
P
=
1.01
3 ba
rs,
a [m
ain]
=
10
–3,
a [H
2O
] =
1;
Sup
pres
sed:
CaH
CO
3+
H2CO3
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PCO2
• What can affect PCO2?– May decrease due to photosynthesis of aquatic
plants; may allow algae to precipitate CaCO3 – Degradation of organic matter in soil zones can
increase PCO2 • CH2O + O2 → CO2 + H2O
– Caves, PCO2 exolves in caves forming speleothems
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Falling SpringsSt. Clair County
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Stalactite
Stalagmite
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Calcite Solubility and pH
• Solubility increases very significantly with increasing acidity of solution (lower pH)– [Ca2+] = 1013.30 [H+]2
– log [Ca2+] = 13.30 – 2 pH• Solubility changes 100x with 1 pH unit change
– Calcite cannot persist in even mildly acidic waters
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0 2 4 6 8 10 12 14–10
–8
–6
–4
–2
0
pH
log
a C
a++
HCO3-
CO2(aq)
CO3--
Calcite
25°C
Walt Tue Feb 21 2006
Dia
gram
HC
O3- ,
T
=
25 °
C ,
P
=
1.01
3 ba
rs,
a [m
ain]
=
10
–3,
a [H
2O
] =
1;
Sup
pres
sed:
CaH
CO
3+
No calcite at pH < ~5.5
H2CO3
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Calcite Solubility and T
• Solubility also affected by T, because equilibrium constants change– Solubility of calcite decreases with increasing
temperature– As particles sink in the oceans, the water gets
colder, and CaCO3 dissolves; none reaches the deep sea bottom
• Calcite compensation depth (CCD)• 4.2 – 5.0 km deep
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Chemical Weathering
• Calcite dissolution is a form of chemical weathering• Congruent dissolution: no new solid phases formed • Incongruent dissolution: new solid formed
– Al silicates usually dissolve incongruently• Products of chemical weathering
– New minerals (clays, oxides, …)– Ions/molecules dissolved; help determine water quality– Unreactive mineral grains (e.g., quartz, garnet, muscovite)
are major source of “sediment”
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Incongruent Dissolution
• KAlSi3O8 + 9H2O + 2H+ Al2Si2O5(OH)4 + 2K+ + 4H4SiO4
• Let’s predict how reaction responds to changes in environmental parameters– What if K+ and/or H4SiO4 removed by flowing
groundwater?– What if there’s an abundance of H2O?– If these particular conditions persist, achieving
equilibrium (saturation) may not be possible
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Reaction Equilibrium
• Can a chemical reaction achieve equilibrium in nature?
• Water/rock ratio is a key variable– The higher the water/rock ratio, the more likely the
reaction goes to completion, not equilibrium• Products removed
– If the ratio is small, the reactions can control the environment and equilibrium is possible
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Geochemical Cycles and Kinetics (reaction rates)
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Geochemical Cycles
• Material is being cycled continuously in the Earth’s surface system
• We can think of the Earth’s surface as consisting of several reservoirs connected by “pipes” through which matter moves– Crust, hydrosphere, atmosphere
• All chemical elements are cycled
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Hydrologic (Water) Cycle
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Carbon Cycle
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Rock Cycle
SedimentMetamorphic
Rocks
IgneousRocks
SedimentaryRocks
Magma formation
Intrusion
Crystalliza
tion
WeatheringTransport
Deposition
Burial
Diagenesis
Lithification
Deformation
Recrystallization
Segregation
Weathering, etc.
SubductionWeathering, etc.
Subduction
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Transfers between reservoirs
Reservoir 2
Reservoir 1
Reservoir 3
d 4,1n
dtd
1,2 ndt
d3,4 n
dt d 2,3n
dt
Reservoir 4
dn = rate of transfer of a componentdt from one reservoir to another = Flux
n = component concentrationt = time
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Steady State
• At Earth’s creation, there was a finite amount of each element
• Very little input of material since then (meteorites, extraterrestrial dust)
• Since these cycles have been going on for a very long time, we assume they are essentially at steady state
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Steady State
• Steady state means that the composition of reservoirs in a cycle does not change over time– No accumulation or loss of the material of interest– Input + any production in the reservoir = outflow + any
consumption in the reservoir– The mass balance = 0; no creation or loss of material
• In the Earth surface environment, especially the oceans and atmosphere, cycling of materials has been occurring at near steady-state
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Steady State
Reservoir 2
Reservoir 1
Reservoir 3
d1,2 n
dt
d 2,3n
dt
d1,2ndt
d2,3ndt
=
d2ndt
= 0
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Residence Time
• Residence time is the average time a molecule spends in a reservoir between the time it arrives and the time it leaves
• Determined by dividing the amount in the reservoir by the flux in (or out) 2n
d1,2n
dt
T =
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Residence time (example)
• Suppose we have a 50 L tank of water, with a flux in = flux out = 5 L/min; what is the residence time?
50 L5 L/min 5 L/min
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Residence time (example)
• Because the water flux in = flux out, it’s at steady state, so dnH2O/dt = 0
• T = 50L = 10 minutes 5L/min• This is the time required to add or subtract 50 L of
water
50 L5 L/min 5 L/min
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Residence time (example)
• However, since there is mixing in the reservoir, not every molecule of H2O is replaced every 10 minutes
• Some molecules will remain in longer, some exit more quickly
5 L/min 5 L/min
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Cycles and reaction rates
• As materials cycle through the Earth, they are moved and transformed at various rates (the “pipes” connecting reservoirs)
• Transport processes and chemical reactions take time
• Kinetics is the study of reaction rates