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Acid-Base Geochemistry Arrhenius’ definition: –Acid any compound that releases a H + when dissolved in water –Base any compound that releases an OH - when dissolved in water Bronstead-Lowry’s definition: –Acid donates a proton –Base receive/accept a proton Lewis’ definition: –Acid electron pair donor acceptor –Base electron pair donor
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Conjugate Acid-Base pairs Generalized acid-base reaction: HA + B A + HB A is the conjugate base of HA, and HB is the conjugate acid of B. More simply, HA A - + H + HA is the conjugate acid, A - is the conjugate base H 2 CO 3 HCO 3 - + H +
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Hydrolysis M z + H 2 O M(OH) z-1 + H + Reaction of a cation, which generates a H + from water is a hydrolysis reaction Described by the equilibrium constant Ka Hydrolysis also describes an organic reaction in which the molecule is cleaved by reaction with water…
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AMPHOTERIC SUBSTANCE Now consider the acid-base reaction: NH 3 + H 2 O NH 4 + + OH - In this case, water acts as an acid, with OH - its conjugate base. Substances that can act as either acids or bases are called amphoteric. Bicarbonate (HCO 3 - ) is also an amphoteric substance: Acid: HCO 3 - + H 2 O H 3 O + + CO 3 2- Base: HCO 3 - + H 3 O + H 2 O + H 2 CO 3 0
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Strong Acids/ Bases Strong Acids more readily release H+ into water, they more fully dissociate –H 2 SO 4 2 H + + SO 4 2- Strong Bases more readily release OH- into water, they more fully dissociate –NaOH Na + + OH - Strength DOES NOT EQUAL Concentration!
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Acid-base Dissociation For any acid, describe it’s reaction in water: –H x A + H 2 O x H + + A - + H 2 O –Describe this as an equilibrium expression, K (often denotes K A or K B for acids or bases…) Strength of an acid or base is then related to the dissociation constant Big K, strong acid/base! pK = -log K as before, lower pK=stronger acid/base!
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LOTS of reactions are acid-base rxns in the environment!! HUGE effect on solubility due to this, most other processes Geochemical Relevance?
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Dissociation of H 2 O H 2 O H + + OH - K eq = [H + ][OH - ] log K eq = -14 = log K w pH = - log [H+] pOH = - log [OH-] pK = pOH + pH = 14 If pH =3, pOH = 11 [H + ]=10 -3, [OH - ]=10 -11 Definition of pH
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pH Commonly represented as a range between 0 and 14, and most natural waters are between pH 4 and 9 Remember that pH = - log [H + ] –Can pH be negative? –Of course! pH -3 [H + ]=10 3 = 1000 molal? –But what’s ?? Turns out to be quite small 0.002 or so…
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pK x ? Why were there more than one pK for those acids and bases?? H 3 PO 4 H + + H 2 PO 4 - pK 1 H 2 PO 4 - H + + HPO 4 2- pK 2 HPO 4 1- H+ + PO 4 3- pK 3
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Methods of solving equations that are ‘linked’ Sequential (stepwise) or simultaneous methods Sequential – assume rxns reach equilibrium in sequence: 0.1 moles H 3 PO 4 in water: –H 3 PO 4 = H + + H 2 PO 4 2- pK=2.1 –[H 3 PO 4 ]=0.1-x, [H + ]=[HPO 4 2- ]=x –Apply mass action: K=10 -2.1 =[H + ][HPO 4 2- ] / [H 3 PO 4 ] –Substitute x x 2 / (0.1 – x) = 0.0079 x 2 +0.0079x-0.00079 = 0, solve via quadratic equation –x=0.024 pH would be 1.61 Next solve for H 2 PO 4 2- =H + + HPO 4 - …
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BUFFERING When the pH is held ‘steady’ because of the presence of a conjugate acid/base pair, the system is said to be buffered In the environment, we must think about more than just one conjugate acid/base pairings in solution Many different acid/base pairs in solution, minerals, gases, can act as buffers…
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Henderson-Hasselbach Equation: When acid or base added to buffered system with a pH near pK (remember that when pH=pK HA and A- are equal), the pH will not change much When the pH is further from the pK, additions of acid or base will change the pH a lot
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Buffering example Let’s convince ourselves of what buffering can do… Take a base-generating reaction: – Albite + 2 H 2 O = 4 OH- + Na + + Al 3+ + 3 SiO 2(aq) –What happens to the pH of a solution containing 100 mM HCO3- which starts at pH 5?? –pK 1 for H 2 CO 3 = 6.35
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Think of albite dissolution as titrating OH - into solution – dissolve 0.05 mol albite = 0.2 mol OH - 0.2 mol OH- pOH = 0.7, pH = 13.3 ?? What about the buffer?? –Write the pH changes via the Henderson-Hasselbach equation 0.1 mol H 2 CO 3(aq), as the pH increases, some of this starts turning into HCO3 - After 12.5 mmoles albite react (50 mmoles OH-): –pH=6.35+log (HCO3 - /H 2 CO 3 ) = 6.35+log(50/50) After 20 mmoles albite react (80 mmoles OH - ): –pH=6.35+log(80/20) = 6.35 + 0.6 = 6.95
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Bjerrum Plots 2 D plots of species activity (y axis) and pH (x axis) Useful to look at how conjugate acid-base pairs for many different species behave as pH changes At pH=pK the activity of the conjugate acid and base are equal
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Bjerrum plot showing the activities of reduced sulfur species as a function of pH for a value of total reduced sulfur of 10 -3 mol L -1.
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Bjerrum plot showing the activities of inorganic carbon species as a function of pH for a value of total inorganic carbon of 10 -3 mol L -1. In most natural waters, bicarbonate is the dominant carbonate species!
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