Post on 18-Jun-2020
Geochemical diversity of hydrothermal systems: Thermodynamic constraints
on biology
Wolfgang BachUniversity of Bremen, Germany
InterRidge Theoretical Institute: Biogeochemical Interaction at Deep-Sea VentsWoods Hole Sept 10-14, 2007
Lithosphere-Biosphere Interactions in Hydrothermal Vents
Driven by Driven by geochemicalgeochemical
energy energy ––powered by
geofuels
Highly diverse: chemicallyand biologically
Dynamically linkedDynamically linkedwith plate tectonicswith plate tectonics
Plate Tectonic - Igneous Genesis
1. Mid-ocean Ridges2. Intracontinental
Rifts3. Island Arcs4. Active Continental
5. Back5. Back--arc Basinsarc Basins6. Ocean Island 6. Ocean Island
BasaltsBasalts7. Miscellaneous Intra7. Miscellaneous Intra--
Continental ActivityContinental ActivityMargins
Winter (2003)
3,5) Subduction zonesRecycling ofvolatiles (and solutes) in Re-gassing the mantle(C,S,H) Wet melting High f O2
1) Mid-ocean ridgesMelting of depleted and degassed upper mantle
Magmas have low gas contentsDry melting Low f O2
6) Ocean island volcanoesMelting of deeper, less degassed mantle
Magmas have moderate gas contents(C,H) Low f O2
Winter (2003)
Plate Tectonic - Igneous Genesis
Geofuel diversity in submarine geotectonic settings
Serpentinite-hostedBasalt-hosted
Arc-related
MOR, Ocean IslandsMOR, Ocean IslandsBasaltBasalt--hostedhosted-- pH 3 to 5pH 3 to 5-- Relatively oxidizing Relatively oxidizing conditionsconditions-- Variable HVariable H22--COCO22 volatile volatile
flux flux -- Global relevanceGlobal relevance
MOR, SubductionMOR, SubductionFelsicFelsic rockrock--hostedhosted-- pH <1pH <1--33-- Very oxidizing conditions Very oxidizing conditions -- Variable HVariable H22OO--COCO22--SOSO22--
HClHCl volatile flux volatile flux -- Variable water (variable Variable water (variable
boiling temperatures)boiling temperatures)
Diversity of systems: physical/chemical differences
MOR, SubductionMOR, SubductionPeridotitePeridotite--hostedhosted-- pH 3 to 12pH 3 to 12-- Reducing conditionsReducing conditions-- Negligible magma volatile Negligible magma volatile
flux?flux?-- AbioticAbiotic organics? organics? -- Early Earth analogsEarly Earth analogs
Serpentinization and hydrogen
a. F420 autofluorescence of a biofilmb. Biofilm cells encased in EPSc. F420 autofluorescence of methane-metabolizing Archaead. FISH photomicrograph confirming that the F420-fluorescent cells are Archaea
Brazelton et al., 2007
Boetius, 2005N&V
??
0 2 4 6 8 10 12 14 16
Temperature (ºC) / Concentration (mmol/kg)
T/100
Cl/100
Si/2
H2S*2
CO2
CH4*5
H2
Mafic/Ultramafic Vent Fluid Chemistry Comparison
RainbowLogatchevMARKTAG
Peridotite-Hosted Hydrothermal Systems
Data: Charlou et al. (2002)
Peridotite-Hosted Hydrothermal Systems
2FeO + H2O Fe2O3 + H2
4H2 + CO2 CH4 + 2H2O
??
Recharge zone
Upflow zone
Reaction zone
Peridotite (± altered)Gabbro intrusion
Serpentinization: Geochemical ModelingGeochemical reaction path model (EQ3NR/6)
-7
-6
-5
-4
-3
-2
-1
0
100 200 300 400
aSiO
2,aq
(M)
Ol+
Tlc+
WSe
rp
Ol+
W
Serp
+Brc
BrcSerp
SerpTlc
OlSerp
TlcQtz
MgO-SiO2-H2O phase relations at 500 bar
Temperature (°C)
Serpentinization of the oceanic lithosphere
OlTlc
2
34
1Internally buffered
Externally controlled
1
Phase relations
Serpentinization: Geochemical Modeling
0.01
0.1
1
125 225 325 425
Temperature (°C)
Mol
es M
iner
als
OlivineMagnetiteSerpentineBruciteCpxTremoliteTalcAndradite
Water/Rock ratio4 2.5 2.0 1.25 1.0
12
34
-6
-5
-4
-3
-2
-1
0
125 175 225 275 325 375 425
Temperature
Log
Mol
es S
olut
es/M
iner
als
SiO2H2Magnetite
Serpentinization: Geochemical Modeling
12
3
4
Fluid compositions
Hydrogen yields in serpentinization are high, because phase assemblages are low silica activity
1.5Fe2SiO4 + H2OFe3O4 +
1.5SiO2(aq) + H2(aq)
Arc volcano hydrothermal system
Gary Massoth et al.
Embley et al. (2004)
Mariana and other arc systemssulfuric and carbonic acid springs
Manus Basin, Papua New Guinea
New Britain
New Ireland
North Su
Active flows of native sulfur on seafloor
Hundreds of acid-sulfate springs, fluid pH as low as 0.9
0
200
400
600
800
1000
0 10 20 30 40 50 60Mg (mmol/kg)
SO4 (
mm
ol/k
g)
NS1NS2D1D2
“Acid Springs” Manus Basin
magmatic fluid
SW
DESMOS
North Su
SO42-
Magmatic SO2 Disproportionation
4SO2 + 4H2O = H2S + 3H2SO4
3SO2 + 2H2O = S0(s) + 2H2SO4
Slide from Jeff Seewald
oooo022 )()( SaqHaqSHr GGGG Δ−Δ−Δ=Δ
H2(aq) + S0 → H2S(aq)
rrr QRTGG ln+Δ=Δ o
)()(
)()(
)(
)(
aqHaqH
aqSHaqSH
SaqH
aqSHr
22
22
02
2
mm
aaa
Qγγ
==
Geochemistry – Biology relations: Gibbs Free Energy
( ) dPVTdCTdTC298TSGGP
1
T
298P
T
298P298fP,T ∫∫∫ +−+−−Δ=Δ oooooo ln
Slide from Jan Amend, redrawn from McCollom & Shock (1997)
Energetics from mixing hydrothermal fluids with seawater
Carbon fixation rate = f(ΔG, T, …)Growth,Maintenance
Unstable phase/species
Me(II) Me(III)KineticKineticBarrierBarrier
CO2,aq
Me2+ + ¼ O2,aq + H+ = Me3+ + ½ H2O (Step of overall reaction that can be mined for energy)
Stable phase/species
Enzymaticcatalysis
ASSIMILATION
The basic principle
ΔG = ΔGo + RT ln QQ = (aMe3+ a½
H2O)/(aMe2+ aH+ a¼O2,aq)
DISSIMILATION
Thermodynamics Tracing the energy across the interface between geology and biology
• What is life in terms of thermodynamics?- Sustaining disequilibria … and- increasing entropy … by- using energy!
• What is the source of the energy?– Light (photosynthesis)– Chemical bonds in organics (heterotrophy)– Electron transfers (chemosynthesis)
Thermodynamics in Biology
ΔG > 0ΔS < 0
ΔG < 0ΔS > 0
ΔGtotal < 0ΔStotal > 0
Zygote Dog
Dog food Dog shit
ΔG = ΔH -TΔS
ΔG > 0ΔS < 0
ΔG < 0ΔS > 0
ΔGtotal < 0ΔStotal > 0
e-donor (food), e-acceptor (e.g., O2)
ΔG = ΔH -TΔS
C,N,H,O,S DNA, RNA,Proteins, Lipids
ASSIMILATION
Reactionproducts &Heat
DISSIMILATION
Only a fraction of the energy can be used to make biomass
Energetic costs of building biomass (from McCollom & Amend, 2005)
In theory (McCollom & Amend, 2005)1.4 kJ / g cellular biomass (anaerobes)18.4 kJ / g cellular biomass (aerobes)Anabolic advantage of living anaerobically
In reality (Heijnen & van Dijken, 1992)30-40 kJ / g cellular biomass (anaerobes using H2 as e-donor)80-170 kJ / g cellular biomass (others)
Only about 10% efficiency90% get lost in form of heat and waste productsThis is increasing entropy in the surrounding
Bioenergetics
Chemolithoautotrophic biomass production estimates
• Axial hydrothermal vents: ~1013 g C/ yr (McCollom and Shock, 1997)
• Hydrothermal plumes: ~1012 g C/ yr (McCollom 2000)
• Ridge flanks/weathering: ~1012 g C/ yr (Bach and Edwards, 2003)
• Photosynthetic: ~1017 g C/ yr (Whitman et al., 1997)
• Sulfate reduction in marine sediments: ~2 x 1012
g C/ yr (Bach and Edwards, 2003 based on sulfate flux rates from D’Hondt et al., 2002)
What reactions are exergonic?
McCollom & Shock (1997)
What reactions support how much biomass?
Max. biomass production (mg / kg vent fluid)0 20 40 60 80 100
Hydrogen ox.
Methane ox.
Fe(II) ox.
Sulfide ox.
Sulfur ox.
Acid-sulfatespringsBasalt-hosted
Peridotite-hosted
??
Hydrogen can be generated abiotically by:(1) Reactions between C-O-H(-S) species in melts and vapors(2) Decomposition of methane at T>600°C(3) Radiolysis of water by radioaktive decay of U, Th, and 40-K(4) Catalysis of silicates under stress in the presence of water(5) Hydrolysis by ferrous minerals in mafic and ultramafic rocks
Away from magmatic centers, only pathways 3-5 are viable. (3) Radiolysis can support on the order of 1,000-10,000 cells per
cm3 in marine sediments (Spivack et al., in press)(4) Happens, but is likely not a continuous source of hydrogen(5) Investigated here
Sources of dihydrogen
Hydrogen demand and supply
Growth
MaintenanceSurvival
Hoehler et al. (2004) Example for methanogens
• Source: Water-rockInteraction @ T=2-120°C
• Source: Water-rock interaction @>350-400°C, followed by mixing with cold seawater
1
10
100
1000
0 20 40 60 80 100 120
Temperature
Wat
er-to
-rock
ratio
0
20
40
60
80
100
120
0 20 40 60 80 100 120Temperature (°C)
Hydrogen demand and supply
Growth
MaintenanceSurvival
Hoehler et al. (2004) Example for methanogens
Seawater-basaltinteraction
Seawater-peridotiteinteraction
Hydrogen demand and supply
Sulfur isotope systematicsbasalt-serpentinite comparison
0%
10%
20%
30%
40%
50%
60%
-60 to -50
-50 to -40
-40 to -30
-30 to -20
-20 to -10
-10 to -5-5 to 0
0 to 55 to 10
10 to 20
20 to 30
δ34S
Freq
uenc
y
Freshbasalt
Sea water
Serpentinite(n=30)
Basalts(n=133)
Isotopic record of sulfate reduction in basalt and serpentinite
Data: Jeff Alt
Growth
MaintenanceSurvival
All redox-rxnsallowed
All redox rxnssuppressed
Hydrogen demand and supply
Logatchev fluidmixed with sea water
H2-O2 is allowed to equilibrate
Seawater – vent fluid mixing
Growth
MaintenanceSurvival
1 mM H2(aq)
12 mM H2(aq)[Logatchev HF]
5 mM H2(aq)
Hydrogen demand and supply
Seawater – vent fluid mixing
Growth
MaintenanceSurvival
0.3 mM O2(aq)
0.1 mM O2(aq)
0.2 mM O2(aq)
Hydrogen demand and supply
Seawater – vent fluid mixing
Summary
• Vent fluid compositions differ fundamentally in different plate tectonic settings.
• Phase equilibria in the deepest and hottest part of hydrothermalsystems set the fluid chemistry that is further modified by mixing with cold seawater, creating disequilibria
• Another way of creating habitable conditions for microbial life is in water-rock reaction systems running at temperatures too low for the system to reach equilibrium
• Life is ineffcient in harvesting the geochemical energy, but relations between the amount of energy and the production of biomass can be expected
• The primary fuel for microbial biomass production is: H2S in basalt-hosted, H2 and CH4 in serpentinization, and S and Fe in felsic rock hosted systems
• In mixing environments, the transition between anoxic and oxic conditions depends on the compositions of the mixing fluids and the kinetics of the H2-consuming redox reactions
Acknowledgments
For discussions and materials:• Tom McCollom, Dionysis Foustoukos, Jan Amend, Art Spivack
(Thermodynamics and bioenergetics)• Katrina Edwards (Deep biosphere)• Jeff Seewald, Paul Craddock, Eoghan Reeves (Manus Basin fluid
chemistry)• Frieder Klein, Michael Hentscher (Geochemical modeling)• Ron Frost (Petrology)• Nicole Dubilier (Geofueled vent biology)
For funding:• NSF and DFG
• InterRidge folks for invitation
-7
-6
-5
-4
-3
-2
-1
0
100 200 300 400
Temperature (°C)
aSiO
2,aq
(M)
Ol+
Tlc+
WSe
rp
Ol+
W
Serp
+Brc
BrcSerp
SerpTlc
OlSerp
TlcQtz
MgO-SiO2-H2O phase relations at 500 bar
Silica-metasomatism in the oceanic lithosphere
Ol+BrcSerp
OlTlc
Serp+EnTlc
Experiments (Allen&Seyfried. 2003)
Nature (Logatchev, Rainbow)