Particle charge and Dispersions i in liquids: id suspensions, emulsions, and foams ACS National Meeting March 21 22, 2009 Salt Lake City
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Electro-osmosis and electrophoresis Voltaic reports the pile in 1800. Steady power. _ + Napoleon rewards Volta 1801. Reuss reports this experiment in 1809. Electro-osmosis of water. Sand Clay Electrophoreis of clay particles. 2
Electrokinetic phenomena Microelectrophoresis Sedimentation potential Electro-osmosis Streaming potential (BIC) 3
+ - - + + + Particle charge Electroacoustic measurements + E E + - - + + + - - λ/2 + + + - - The technique uses an ultrasonic pressure wave to perturb the equilibrium double layer. This polarization generates an alternating electric field called the Colloid Vibration Potential: E CVP 2 p ϕ ρ 2 ρ 1 ε 0 D ζ = λ0 ρ1 η The great advantage is its use at high particle concentrations 4
The science of flow Shearing stress = Force/Area = F/A = Newton/m 2 Rate of shear = Change of velocity with distance = dv/dx = sec -1 Force/Area Newton s equation for viscous flow: F A dv = η dx shear stress Newton sec η = = =Pascal-sec 2 shear rate m Kinematic viscosity = Newtonian viscosity/density = Stoke 5
Couette viscometer Bob h R b R c Cup In modern Couette viscometers the bob is either driven with a known stress and the resulting angular velocity measured or it is driven at a known angular velocity and the required stress measured. The first provides viscosity as a function of shear stress, the latter provides viscosity as a function of shear rate. CW Macosko : Principles, Measurements, and Applications VCH:New York, 1994. 6
Cone and plate rheometer Rotation Cone Plate Sample Consists of a flat plate and a cone with an apex angle of nearly 180 o For such a geometry, the rate of shear is very nearly constant over the entire sample so that a well defined viscosity is measured. The rate of shear is changed by changing g the rotational velocity of the cone. 7
Rheological behavior 8
Pseudoplastic flow 4 ) Sh hear rate (s sec -1 10-4 1. 6 1.2 0.8 0.4 0.0 ( f ) ( e ) ( d ) ( c ) Shear stress (Pa) ( b ) ( a ) (a) 0. 00 (b) 0.02 (c) 0.04 (d) 0.06 ( e ) 0.10 (f) 0.30 0 1 0 2 0 3 0 4 0 5 0 6 0 7 0 Rheograms of 20 w% deionized kaolin slurries at several levels of tetrasodium pyrophosphate* addition. The figures on the curves indicate percent TSPP per weight of clay. An extrapolation of the linear region determines an apparent yield point. *Na 4 P 2 O 7 9
Dilatancy 400 11.3% 11.7% Shear rate (r.p.m.) 300 12.0% 200 100 12.4% 12.7% 0 0 200 400 600 800 1000 Shear stress (gram s) Dilatant flow of a series of suspensions of red iron oxide in an aqueous solution of sodium lignin sulfonate at 10% concentration at 30 o C. The volume concentrations ti of solids are noted on the curves. Fischer p. 200 10
Thixotropy Thixotropic behavior is a temporary destruction of structure by stirring or shaking, and may be measured as the time required to heal heal. The diagram depicts rheological behavior of a thixotropic system as measured with a rotational viscosimeter. The area and nature of the thixotropic loop depends upon the type of instrument and the circumstances of measurement. 11
of quicksand At high stress (explorer falling into the quicksand), the viscosity drops, and the explorer sinks. When the thrashing is finished. The viscosity climbs, and hope fades. Yield stress The yield stress increases with concentration. The solution is dilution! Volume fraction Khaldoun et al., Nature, 437, 635, 2005. 12
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