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GE0-3112 Sedimentary processes and products Lecture 2. Fluid flow and sediment grains. Geoff Corner Department of Geology University of Tromsø 2006 Literature:

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Presentation on theme: "GE0-3112 Sedimentary processes and products Lecture 2. Fluid flow and sediment grains. Geoff Corner Department of Geology University of Tromsø 2006 Literature:"— Presentation transcript:

1 GE0-3112 Sedimentary processes and products Lecture 2. Fluid flow and sediment grains. Geoff Corner Department of Geology University of Tromsø 2006 Literature: - Leeder 1999. Ch. 4, 5 & 6. Sedimentological fluid dynamics.

2 Contents ► 2.1 Introduction - Why study fluid dynamics ► 2.2 Material properties ► 2.3 Fluid flow ► 2.4 Turbulent flow ► Further reading

3 2.1 Introduction - Fluid dynamics ► Concerns how fluids transport sedimentary particles. (NB. Fluids are liquids and gasses) ► Fluid flows can be described using basic physics, although sedimentary particles add complication.

4 Why study fluid dynamics? ► Examples of practical problems  Pebbles on a sandy surface  Slidden boulder in Death Valley  Deformation structure

5 Notes on scientific notation ► Fundamental units of physical dimension (dimensional analysis): M (mass), L (length), T (time). ► System of units of measurement:  Metre-kilogram-second (SI, Systèm Internationale d’Unités).  CGS, centimetre-gram-second (informal) ► Greek letters (used in formulas).

6

7 2.2 Material properties ► Three states of matter (solid, liquid, gas); have different properties and behaviour. ► Solids (e.g. rock, ice): have strength and resist shear (limited...deformation). ► Liquids (e.g. water): deform readily under shear stress; incompressible. ► Gasses (e.g. air): deform readily under shear stress; compressible ► NB. Some substances have behaviour intermediate between liquid and solid (e.g. mud-water mixtures).

8 Material properties of fluids ► Density ► Viscosity Density and viscosity are temperature dependent.

9 Density ► Density (ρ) is mass (m) per unit volume [ML-3; kg/m 3 ]. ► Solids (rock, ice, sediments) have strength and resist shear (limited...deformation). ► Liquids (water) deform readily under shear stress but are incompressible. ► Gasses (air) deform readily under shear stress and are compressible. ► NB. Some substances have behaviour intermediate between liquid and solid (e.g. mud-water mixtures). ► Density affects:

10  Fluid momentum  Buoyancy (density ratio)

11 Density vs. temperature and pressure ► Water density decreases with temperature (above 4 o C) and increases with pressure. ► Air density decreases with temperature and increases with pressure. WaterAir

12 Example 1: thermal stratification in lakes

13 Density vs. salinity ► Water density inceases with salinity. ► Salinity examples:  Freshwater lakes Norway:  Freshwater lakes Norway: <c. 0.4‰  Brackish water fjords Norway:  Brackish water fjords Norway: c. 29-3‰  Coastal seawater Norway:  Coastal seawater Norway: 33-29‰  Seawater tropics:  Seawater tropics: 34-35‰

14 Example 2a: saline stratification in fjords Syvitski 1987

15 Example 2b: density driven thermohaline circulation in the ocean ► Example of flow generated by density and temperature differences: thermohaline flow

16 Density vs. sediment content ► Density increases with sediment content

17 Example 3: Hypo- and hyperpycnal flows beyond river mouths ► Hypopycnal = less dense ► Hyperpycnal = more dense ► Density differences between the inflowing and ambient water can be caused by a combination of temperature, salinity and sediment concentration differences.

18 Viscosity ► Dynamic (or molecular) viscosity (μ): [ML -1 T -1 ; kg/m s, or N s/m 2 ] (A measure of a fluid’s ability to resist deformation) ► Kinematic viscosity (ν):  v=μ/  [L 2 T -1 ; m 2/ s] (Ratio between a fluid’s ability to resist deformation and its resistance to acceleration)

19 Dynamic (molecular) viscosity ► Viscosity controls the rate of deformation by an applied shear, or: ► Viscosity is the proportionality factor that links shear stress to rate of strain: ► Dimensions are: [ML -1 T -1 ; kg/m s] ► Viscosity is much higher in water than in air. Shear stress (tau) Viscosity (mu) Strain rate

20 Viscosity vs. temperature ► Viscosity varies temperature:  In water it decreases.  In air it increases.

21 Viscosity vs. sediment concentration ► Fluid viscosity increases with sediment content.

22 Viscosity vs. shear rate ( Newtonian and Non-Newtonian behaviour ) ► Newtonian fluids:  Constant viscosity at constant temperature and pressure.  Continuous deformation (irrecoverable strain) as long as shear is maintained. ► Non-Newtonian fluids:  Viscosity varies with the shear rate.  Various types of Non-Newtonian behaviour/substances: ► Pseudoplastic, Dilatant, Thixotropic, Rheopectic.

23 Non-Newtonian behaviour ► Pseudoplastic: μ decreases as rate of shear increases. ► Dilatant: μ increases as rate of shear increases. ► Thixotropic: μ decreases with time as shear is applied. ► Rheopectic: μ increases with time as shear is applied.

24 Examples from nature Newtonian viscous fluid Non- Newtonian Increasing viscosity

25 2.3 Fluid flow ► Flow types ► Controlling forces ► Dimensionless numbers ► Flow steadiness and uniformity ► Flow visualisation and flow lines ► Laminar and turbulent flow (Reynolds number) ► Turbulent flow

26 Flow types ► Newtonian: continuous deformation (irrecoverable strain) as long as shear stress is maintained (linear stress-strain relationship). ► Plastic: initial resistance to shear (yield stress) followed by deformation.  Bingham plastic: constant viscosity  Non-Bingham plastic: viscosity varies with shear ► Non-Newtonian pseudo-plastic ► Non-Newtonian thixotropic ► Non-Newtonian dilatant

27 Fluid flow – driving forces ► Momentum-driven flows (externally applied forces) (Gravity and pressure differences drive flows) ► Buoyancy-driven flows (Density difference drives flows) (Density difference drives flows)

28 Controlling forces ► Buoyancy forces (density controlled) ► Viscous forces (viscosity controlled) ► Inertial forces (momentum controlled) ► Gravitational forces

29 Dimensionless numbers ► Dimensionless ratios provide scale- and unit-independent measures of dynamic behaviour. ► Two important ratios in fluid dynamics are:  Reynolds number: ratio of inertial to viscous forces  Froude number: ratio of inertial to gravity forces

30 Flow steadiness ► Relates to change in velocity over time  Steady flow - constant velocity  Unsteady flow – variable velocity Steady flow (e.g. steady turbulent river measured over hours) Unsteady flow (e.g. decelerating turbidity current)

31 Flow uniformity ► Relates to change in velocity over distance  Uniform flow - constant velocity (parallel streamlines)  Non-uniform flow – variable velocity (non-parallel sls) Uniform flow (e.g. in channel) Non-uniform (diverging) flow (e.g. at river mouth)

32 Flow visualisation - flow lines ► Streamline - line tangential to the velocity vector of fluid elements at any instant. ► Pathline - trajectory swept out over time (e.g. long exposure of a spot tracer). ► Streakline - instantaneous locus of all fluid elements that have passed through the same point in the flow field (e.g. short exposure of a continuously introduced tracer. Pathlines StreamlinesStreaklines

33 Flow visualisation – reference frames Streamlines for flow pattern round an object moving to the left through a stationary fluid (Langrangian velocity field) Streamlines for flow past a stationary object (Eulerian velocity field)

34 Laminar and turbulent flow ► Flow type changes with increasing velocity - from laminar to turbulent. from laminar to turbulent. ► The relationship is described by the Reynolds number. Rapid pressure drop/ change in flow type.

35 Reynolds number ► Reynolds number (Re) is the the ratio of viscous forces (resisting deformation) to inertial forces (ability of fluid mass to accelerate). ► The transition from laminar to turbulent flow occurs at about Re = 500 – 2000. Inertial force Viscous force Molecular viscosity Velocity Density Depth

36 Flow patterns ► Laminar flow: parallel flowlines (low Re). ► Turbulant flow: irregular flowlines with eddies and vortices (high Re). Laminar flow Transitional to turbulent flow Turbulent flow Streaklines

37 Velocity distribution in viscous flows Parabolic Newtonian laminar flow velocity profile. Plug-like non- Newtonian laminar flow (e.g. debris flow). Flow retardation in a boundary layer

38 2.4 Turbulent flow ► Turbulent eddies ► Bed roughness ► Flow separation

39 Turbulent eddies Backwash/rip-current eddies at Breivikeidet Eddy movement in x-y space with time (t 1 -t 2 )

40 Instantaneous velocity

41 Bed roughness Turbulent stresses dominate Viscous sublayer Viscous forces dominate +η (Boussinesq’s eddy viscosity)

42 Bed roughness Viscous sublayer (smooth bed) No viscous sublayer (rough bed)

43 Shear velocity and skin friction Smooth Rough

44 Turbulent eddies in air Streaklines viewed in the x-z plane (i.e. plan section) Streaklines viewed in the x-y plane (i.e. flow- parallel vertical section)

45 Components of turbulent eddies Sweep (fast) Burst (slow) Streaks (close to bed)

46 Turbulent eddies in water Flow at successively higher positions above the bed (a- d) Slow flow pattern in viscous sublayer Flow pattern in turbulent boundary layer Macroturbulence in outer regions of flow Sand particle flow in viscous sublayer shown at 1/12 s time intervals ’Sweep’ event

47 Kelvin-Helmholz vortices ► Important mixing mechanism at junction of two fluids, e.g. at junctions of tributaries or mixing water masses, at fronts and tops of density currents, etc. Likely causes of K-H instability: a)-c) velocty differences across boundary layer or in density- stratified flows; d)-e) shear layers produced by pressure differences.

48 Flow separation Boundary layer separation point Boundary layer reattachment zone (downstream)

49 Accelerating flow, decreasing pressure Decelerating flow, increasing pressure, redardation and separation of flow closest to the bed

50 2.5 Sediment grains in fluids ► Settling (Stokes velocity) ► Threshold velocity ► Rolling, saltation and suspension ► Bedload, suspended and washload

51 Settling ► Fall velocity increases with increasing grain size Stokes equation applies: - Low Re (< 0.5) - No viscous flow separation - Low sed. concentration Silt-f.sand Velocity increase reduced: - Higher Re (>1) - Turbulent drag - Non-spherical grains - High sed. concentration NB! Clays flocculate

52 Particle transport ► Critical threshold (shear) velocity  Lift + drag forces = resisting (gravity) forces. ► Low pressure over grains (due to acceleration, cf. Bernoulli’s equation) causes lift.

53 Particles above the bed ► Instantaneous local shear varies due to burst/sweep events. ► Once entrained, drag forces increase relative to lift forces. More drag More lift

54 Threshold velocity ► Threshold velocity for motion increases with increasing grain size. SiltSand Pebbles

55 Impact threshold in air ► Falling grains in air can induce grain motion on impact above the impact threshold velocity. ► Velocity for normal threshold is higher.

56 Grain motion ► Rolling, saltation, suspension

57 Types of transport loads ► Washload ► Suspended load ► Bedload

58 Further reading ► Allen, J.R.L. 1970. Physical processes of sedimentation.  Chapter 1 covers the same ground as Leeder and explains clearly the principles involved; good supplementary reading for aquiring a sound grasp of the physics of fluid dynamics and sedimentation. Alternatively consult the more encyclopedic: ► Allen, J.R.L 1984. Sedimentary structures: their character and physical basis.  A more encyclopedic alternative to the above if it is unavailable.


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