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Geology 3550 Sedimentation & Stratigraphy Weathering Weathering Weathering is ….. I Controls III Products II Mechanisms IV Temporal Patterns Mechanical Chemical I Controls on Weathering • Source Rock • Climate • Topography • Tectonics Fractures are very important Surface Area Effects Not all rocks are created equal…… ~1900oC Low Temperature high Bowen’s Reaction Series ~500oC GRANITE * Quartz – SiO2 * Orthoclase (K-spar) – KAlSi3O8 Albite (Na plag) – NaAlSi3O8 Muscovite Biotite BASALT * Pyroxene – Mg,Fe,Ca,Na,Al (Si2O6) * Anorthite (Ca plag) – CaAl2Si2O8 Olivene – Fe/Mg2SiO4 Relative Stability of Common Rocks low high Limestone Dolostone Siltstone Sandstone Basalt Granite Chert Quartzite I Controls on Weathering • Source Rock • Climate • Topography • Tectonics temperature, moisture, plants Water is a polar molecule Hydrogen Bonds Covalent Bonds Water is the “universal solvent” Inverse relationship between topographic relief and weathering Slope steep gentle weathering little intense II Mechanisms of Weathering Mechanical • Physical Exfoliation Frost Wedging Impacts Spheroidal Weathering • Biological Root Wedging/Plucking The Importance of “Plants” Physical Weathering – Root Wedging (Also important in chemical weathering – Organic acids and CO2 generation) II Mechanisms (cont.) Chemical • Inorganic Hydrolysis Carbonation Solution Oxidation Hydration Halmyrolysis Water is very important CO2 is very important Hydrolysis Reactions Al silicate + H2O + CO2 ---> clay + Si (SiO2 or H4SiO4) (e.g. Orthoclase/K-spar -- KAlSi3O8) Note: H2O + CO2 <—> H2CO3 (carbonic acid) • Illite – From moderate weathering of granites K (Al, Mg, Fe) (Al Si4) O10 (OH)2 Common Clays • Montmorillonite – From moderate weathering of basalts (Na, Ca) (Al, Mg)2 Si4O10 (OH)2 . nH2O • Kaolinite – From intense weathering of igneous source 3 Al2 (Si2O5) (OH)4 GRANITE * Quartz – SiO2 * Orthoclase (K-spar) – KAlSi3O8 Albite (Na plag) – NaAlSi3O8 Muscovite Biotite BASALT * Pyroxene – Mg,Fe,Ca,Na,Al (Si2O6) * Anorthite (Ca Plag) – CaAl2Si2O8 Olivene – Fe/Mg2SiO4 GRANITE BASALT * Quartz – SiO2 * Orthoclase (K-spar) – KAlSi3O8 Albite (Na plag) – NaAlSi3O8 Muscovite Biotite * Pyroxene – Mg,Fe,Ca,Na,Al (Si2O6) * Anorthite (Ca plag) – CaAl2Si2O8 Olivene – Fe/Mg2SiO4 Hydrolysis Quartz – SiO2 Illite – K Clay (K loss) Montmorillonite – Mg Clay More weathering (Mg loss) Kaolinite (Si loss) More weathering Bauxite – Al(OH)3 Silic Acid – H4SiO4 (Fe loss) Hematite – Fe2O3 Bauxite (trace) Carbonation Reactions Carbonate + H20 +CO2 —> Ca++ + 2HCO3 Produce microkarst, karst terranes, sink holes, and caves Microkarst - Jamaica Oxidation Reactions Metal + O2 (+ H20) —> metal oxide (e.g. Pyrite, FeS2) —> (Hematite, Fe2O3 + SO4 + H) (e.g. Pyroxene, ~FeSiO3) —> (Hematite, Fe2O3 + SiO2) Red Beds Additional Reactions • Direct Solution Soluble mineral + H2O <—> dissolved ions in solution (e.g. Anydrite - CaSO4, Halite - NaCl) <—> Ca++ Na++ Cl-- SO4-• Hydration Nonhydrated mineral + H2O —> hydrated mineral (e.g. Hematite - Fe2O3) —> (Goethite - 2Fe OOH) with a change in volume (e.g. Anhydrite - CaSO4) —> (Gypsum - CaSO4 . 2H2O) Halmyrolysis - Weathering of Ocean Crust Black Smoker II Mechanisms (cont.) Chemical Weathering • Biological Organic Acids CO2 Chelation Fe, Al silicate + organic compound —> chelated cations in solution (e.g. Lichen attacking rocks) III Products of Weathering • Resistates **Quartz • Secondary Minerals **Clays Oxides Hydroxides • Soils – weathered rock plus organic material • Dissolved Ions HCO3 Ca H4SiO4 SO4 Cl Na Mg K These become chemical sedimentary rocks – e.g. …….. IV Temporal Patterns • Cyclical changes driven by tectonics and climate • Unidirectional changes driven by planetary and biological evolution - Atmospheric oxygen by 2.0Ga - Appearance of land plants by ~ 400Ma - Appearance of grasses by ~100Ma Geology 3550 Sedimentation & Stratigrphy Erosion, Transport and Deposition of Sediments Ice and mass movements are capable of moving large particles, but are volumetrically less significant than wind and water Erosion, Transport and Deposition of Sediments I Controls On Erosion II Mechanisms of Erosion and Transportation III A Quick Look at Fluid Flow IV Streams as Transport Agents V Deposition of Sediments I Controls On Erosion •Source Consolidated vs unconsolidated Fractured vs not Crystalline vs sedimentary Weathered vs fresh •Climate High precipitation contributes to erosion Plants reduce erosion •Topography Erosion rate positively correlated with uplift rate II Mechanisms of Erosion and Transportation •Mass Movements Dry Rock Fall, Rock Slide Fluid-Assisted Grain Flows, Fluidized Sed Flows, Debris Flows, Turbidity Currents •Ice Abrasion Plucking •Wind Abrasion (Ventifacts) Deflation (Desert Pavements?) •Water (flowing water and waves) Abrasion and Chipping Dissolution Hydraulic Lifting/Entrainment II Mechanisms of Erosion and Transportation (cont.) •Ice -Erosion Abrasion Plucking Oversteepened slopes - Transport Material carried on and in the ice Tills characterized by poor sorting, little rounding Outwash and wind blown deposits will show better sorting Extensive loess deposits are associated with the last glaciation II Mechanisms of Erosion and Transportation (cont.) •Wind - Erosion by Abrasion (Ventifacts) Deflation (Desert Pavements?) Favored by dry climate (few plants) - Transport involves fine material (air may be viewed as a very low viscosity fluid) - Deposits tend to be very well sorted III A Quick Look at Fluid Flow •Fluids (air and water) Fluid vs Plastic Laminar vs Turbulent Flow Shear Stress (tau τ) Kinematic (nu ν) and Dynamic (mu μ) Viscosity Reynolds (Re) and Froude (Fr) Numbers •Entrainment Bernoulli Effect Drag Force Fluid Force Hjulstrom Diagram Wave Orbital Velocity Laminar vs Turbulent Flow P&S p. 33 Increasing velocity, decreasing fluid viscosity, increasing bed roughness, increasing depth, all contribute to turbulent flow 1 Dynamic Viscosity τ μ = _____ du/dy shear stress rate of deformation (μ = 0.0131 @ 10o C, fresh water) 2 Kinematic Viscosity μ ν = _____ P dynamic viscosity density (mass/unit volume) (P = 0.999gm/c @ 10o C, fresh water) 3 Reynolds Number ULP UL Re = ______ = ______ μ ν where U = velocity (cm/sec) L = depth (or grain dia) cm P = density ratio of fluid inertial forces/fluid viscous forces 500 - 2000, critical threshold for transition from laminar to turbulent 4 Froude Number U Fr = _______ SQRT (g L) where U = velocity (cm/sec) where g = Gravitational constant (981 cm/sec2) ratio of fluid inertial forces/gravitational forces in flow Fr <1 = tranquil flow Fr > 1 = rapid flow predicts sedimentary structures (dunes, antidunes) Forces Acting on a Grain at Rest •Gravity •Friction •Cohesion •Fluid lift force (Bernoulli) •Fluid drag force •Net fluid force P&S p.35 5 Drag Force Τo FD= _____ N Τo = boundary shear stress number of exposed grains γ specific gravity Rh hydraulic radius S ~U slope velocity Waves Wave mechanics •Energy from wind - Velocity, duration, distance (fetch) - Surface cohesion important (from hydrogen bonds between water molecules) Waves (cont.) •Water moves in circular orbits - Orbital diameter decreases with depth - Orbit velocity a function of diameter - Orbits “feel” bottom at depth ~ ½ λ Orbits become more elliptical Wave length decreases Wave height increases Breakers form 6 Wave Orbital Velocity πH Ut = _______________ T sin h (2 π h/L) where L = wavelength (m) T = wave period (sec) H = wave height (m) h = water depth (m) π = pi @ h =1/2 L, wave feels bottom @ h = 1/20 L, orbits very elliptical @ L = 150m, h = 15m, T = 10sec, H = 1m Ut = 30cm/sec (capable of moving ~1mm grain) IV Streams as Transport Agents Terms •Competency - maximum particle size - largely determined by velocity •Capacity - total load - largely a function of discharge (volume) •Discharge - velocity x channel size - input from tributaries and sheet wash - Colorado R at Moab ~100 -700 cubic m/sec - Mississippi R at mouth 173,600 cubic m/sec - Amazon R at mouth 1,800,000 cubic m/sec IV Streams as Transport Agents Terms (cont.) •Velocity - determined by discharge, gradient, channel shape, bed roughness - < 1 to > 30km/hr •Load Dissolved Suspended Saltation Traction IV Streams as Transport Agents •Stream Profile Downstream Changes •Channel shape •Gradient •Tributaries •Discharge •Velocity •Load V Deposition of Sediments •Cause - Decrease in energy Gravity overcomes turbulence and fluid viscosity - Settling Velocity/Stoke's Law - Shape Effects/Zingg Shapes - Maximum Projection Sphericity •Environments of deposition 7 Stokes Law U= C D2 where U = settling velocity (cm/sec) D = sphere dia. (cm) (Ps - Pf) g C= ___________ 18 μ where Ps = density of grain Pf = density of fluid @ D= 0.05cm (1 phi), μ = 0.0131, Pf = 0.999, Ps = 2.65 (quartz) U = 17.2 cm/sec Rg (Reynolds grain #) = 57.3 8 Maximum Projection Sphericity MPS = Cube Root (Ds2/Di Dl) where Ds = minimum axis Di = intermediate axis Dl = maximum axis (all axes are orthogonal) Dl Ds Di multiply MPS by sieve diameter to get equivalent sphere size V Deposition of Sediments •Environments of deposition - examples……… Geology 3550 Sedimentation & Stratigraphy Inorganic Sedimentary Structures I Primary Structures Depositional • Bedding/Stratification - Massive - featureless - Stratified Graded Parallel Cross-stratified Trough Hummocky Tabular Herringbone Climbing • Bedding Surfaces Lenticular Ripples Wavy Dunes Flaser I Primary Structures (cont.) Depositional • Bedding/Stratification - Stratified Graded Parallel Cross-stratified Trough Hummocky Tabular Herringbone Climbing I Primary Structures (cont.) Depositional • Bedding Surfaces Lenticular Wavy Flaser Ripples Dunes Antidunes P&S p. 55 Lower plane bed Flow velocity (and grain size) controls the type of sedimentary structure generated P&S p. 47 I Primary Structures Erosional • Scours/Flute Casts •Tool Marks • Channels • Truncation • Intraclasts II Secondary Structures •Dissolution/Precipitation Vugs Concretions Salt Hoppers Geopetal Fills Mineralized crusts Dendrites Birdseye • Hydration/Dehydration Mud Cracks Syneresis Cracks • Deformational Slump Boudinage Flame Shock Teepee Load Casts II Secondary Structures (cont.) • Hydration/Dehydration Mud Cracks Syneresis Cracks • Deformational Slump Boudinage Flame Shock Teepee Load Casts II Secondary Structures (cont.) • Deformational Slump Flame Teepee Boudinage Shock Ball and Pillow Load Casts Most are associated with high sedimentation rates…… Geology 3550 Sedimentation & Stratigraphy Biogenic Sedimentary Structures Biogenic Sedimentary Structures I Bioturbation II Bioerosion III Biostratification IV “Other” Structures V Biogenic Structures and Diagenesis VI Temporal Patterns Biogenic Sedimentary Structures I Bioturbation • Activities Dwelling Resting Locomotion • Interpretation - Behavior - Ichnofacies - Ichnofabric - Sediment Parameters Feeding Escape Biogenic Sedimentary Structures I Bioturbation (cont.) • Activities Dwelling Resting Locomotion • Interpretation - Behavior - Ichnofacies - Ichnofabric - Sediment Parameters Feeding Escape Biogenic Sedimentary Structures II Bioerosion • Micro - Micritization Blue-green algae • Macro Sponges, bivalves, sea urchins, parrot fish • Interpretation Sedimentation rate Paleobathymetry (photic zone) Biogenic Sedimentary Structures II Bioerosion (cont.) • Micro - Micritization Blue-green algae • Macro Sponges, bivalves, sea urchins, parrot fish • Interpretation Sedimentation rate Paleobathymetry (photic zone) Biogenic Sedimentary Structures III Biostratification • Biograded Bedding • Stromatolites LLH SH • Other Oncoids Ooids • Interpretation Paleobathymetry Salinity? Biogenic Sedimentary Structures III Biostratification (cont.) • Biograded Bedding • Stromatolites LLH SH • Other Oncoids Ooids • Interpretation Paleobathymetry Salinity? Biogenic Sedimentary Structures IV “Other” Structures • Reef / Bioherm / Biostrome / Thrombolite • Concretions • Geopetal Fills Biogenic Sedimentary Structures V Biogenic Structures and Diagenesis • Micritization • Burrow Mottling • Silicified Burrows • Stromatolites and Dolomitization Biogenic Sedimentary Structures VI Temporal Patterns • Little or no burrowing in Precambrian (Requires metazoa, requires body cavity) • Shallow burrowing (few cm) in Cambrian (Implications for intraclasts) • Increased grazing eliminated stromatolites from normal, open marine settings after Camb. • Burrowing depth increase in Devonian (Problems for sessile benthos?) • Major expansion in burrowing in Mesozoic Geology 3550 Sedimentation & Stratigraphy Detrital/ Clastic/ Terrigenous/ Extrabasinal Rocks Detrital/ Clastic/ Extrabasinal/ Terrigenous Rocks I Classification Texture Composition II Rock types these categories are based on texture - size Conglomerate/Breccia Sandstone Siltstone Shale/Mudstone III Diagenesis Eogenesis Mesogenesis Telogenesis Detrital/ Clastic/ Extrabasinal/ Terrigenous Rocks I Classification •Texture - Physical appearance - Grain Size - Grain Shape - Sorting - Grain/Matrix Relationships •Composition - Chemistry and mineralogy II Clastic Rock types •Conglomerate/Breccia Orthoconglomerate (Oligomict, Petromict) Paraconglomerate (Diamictite, Tillite) •Sandstone Arkose Litharenite Quartzarenite/Orthoquartzite Wackes •Siltstone •Shale/Mudstone Kaolinite Chlorite (Fe, Mg, SiO2) Illite (K rich) Glauconite (K, Fe, SiO2)Montmorillonite (Mg rich) II Clastic Rock types (cont.) •Conglomerate/Breccia Orthoconglomerate (Oligomict, Petromict) Paraconglomerate (Diamictite, Tillite) •Sandstone Arkose Litharenite Quartzarenite/Orthoquartzite Wackes •Siltstone •Shale/Mudstone Kaolinite Chlorite (Fe, Mg, SiO2) Illite (K rich) Glauconite (K, Fe, SiO2)Montmorillonite (Mg rich) II Clastic Rock types (cont.) •Conglomerate/Breccia Orthoconglomerate (Oligomict, Petromict) Paraconglomerate (Diamictite, Tillite) •Sandstone Mudrocks Arkose Litharenite Quartzarenite/Orthoquartzite Wackes •Siltstone •Shale/Mudstone Kaolinite Chlorite (Fe, Mg, SiO2) Illite (K rich) Glauconite (K, Fe, SiO2)Montmorillonite (Mg rich) III Diagenesis •Environments - Eogenesis - near surface - Mesogenesis - deep burial - Telogenesis - uplifted, exposed to ground water •Changes - Compaction - porosity reduction - Cementation - porosity reduction - Dissolution - creation of secondary porosity - Formation of new minerals - may increase or decrease porosity Geology 3550 Sedimentation & Stratigraphy Chemical Sedimentary Rocks Chemical/ Precipitates/ Intrabasinal Rocks I Carbonates II Siliceous Rocks III Evaporites IV Phosphates V Sedimentary Ironstones VI Carbon-rich Rocks VI Standard Rock Symbols Chemical/ Precipitates/ Intrabasinal Rocks I Carbonates •Limestone CaCO3 - Origins - Dunham and Folk Classifications - Allochems •Dolostone CaMg(CO3)2 - Models for Dolomitization •Carbonate Diagenesis - Diagenetic Environments - Diagenetic Changes Limestone Origins •Inorganic Precipitation? - Travertine Cave Flowstone Tufa Spring Deposits - Some marine cements? •Organic Precipitation Although most limestones are marine, some do occur in freshwater lakes with high carbonate content (e.g. Bear Lake, UT). Freshwater limestones may be associated with interdune areas in arid regions (e.g. Navajo Sandstone and related rocks in the western US). Descriptive terms for limestones that you should not use Encrinite Oolite Coquina Marl Chalk Noncarbonate Calcareous Shale Shaley, Dolomitic Limestone 50% Shaley Limestone Dolostone Limestone Dolomite 50% Calcareous Dolomite Dolomitic Limestone Calcite Chemical/ Precipitates/ Intrabasinal Rocks I Carbonates •Limestone CaCO3 - Origins - Dunham and Folk Classifications - Allochems •Dolostone CaMg(CO3)2 - Models for Dolomitization •Carbonate Diagenesis - Diagenetic Environments - Diagenetic Changes Dolomitization •Calcite - CaCO3 - is transformed to CaMg(CO3)2 •Favored by high (>1) Mg/Ca ratios in seawater •Most models increase Mg by removing Ca through formation of gypsum and anhydrite •Dorag/Schizohaline/Mixing model does not require high Mg/Ca •Much dolomite forms secondarily during deep burial diagenesis and migration of brines •Stromatolites are often dolomitized as the cyanobacteria contain Mg in photosynthetic pigments Chemical/ Precipitates/ Intrabasinal Rocks I Carbonates •Carbonate Diagenesis - Diagenetic Environments Eogenesis Mesogenesis Telogenesis - Diagenetic Changes Early cementation - little compaction Hardground formation Neomorphism - crystal growth Pressure solution - stylolitization Dolomitization and void formation II Siliceous Rocks - SiO2 •Cryptocrystalline/microcrystalline, not quartz •Precipitated from solution •Occurs in low concentrations in sea water •Different stability field than CaCO3 •Possibly from alteration of volcanic ash Bedded •May come from deep sea siliceous oozes Nodular •Often found replacing burrows or body fossils •E.g. Chert, flint, jasper, chalcedony, opal III Evaporites •Minerals - Gypsum - CaSO4 . H2O and Anhydrite - CaSO4 (76-93% humidity) - Halite - NaCl (67-76% humidity) - Potash ~ KCl (<67% humidity) •Environments - Restricted marine basins - e.g. Permian of Utah, S Texas - Coastal salinas - e.g. S Texas - Sabkahs - e.g. Persian Gulf - Playa lakes - e.g. Great Salt Lake, UT IV Phosphate Deposits ~ Ca(PO4)CO3(F,P,Cl) •A nutrient (like silica) so rare in ocean surface waters requires upwelling •Common at Proterozoic/Phanerozoic boundary breakup of Rodinia? •May have influenced evolution of skeletonized life •Also common in Permian rocks of western U. S. e.g. Phosphoria Fm. in UT, ID, WY •Bone beds may also contain large quantities of phosphates Sil. Oolitic Iron Ores •Important in eastern iron industry (AL, NY) •Due to reworking of heavily weathered soils followed by marine transgression? •Early replacement phenomenon? Sil. Oolitic Iron Ores, Birmingham, AL VI Carbon-rich Rocks •Coals - Environments - Maturation Sequence •Oil and Natural Gas - Environments - Maturation Sequence - Traps •Oil Shales and Tar Sands Coals Require •High productivity - Nutrients - Moisture - Warm •Burial Coal Maturation Sequence •Vegetation •Peat •Lignite •Bituminous •Anthracite Swamp, S LA Carbon-rich Rocks - Oil and Natural Gas Most are marine Requires •High Productivity - Nutrients •Burial and preservation - Deltas ideal Maturation stages •Organic matter - mainly plankton - not dinosaurs! •Kerogen •Petroleum •Natural gas A Successful Petroleum Field Requires •Source rock - fine grained, organic rich •Maturation - time, temperature, pressure •Reservoir rock - high permeability - What reduces permeability? - What increases permeability? •Cap rock or seal - fine grained, non permeable •Trap - Structural - Stratigraphic
