Multimedia : Cartilage Podcast, Dean, et al. J. Biomech ,

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1 3.05 Nanomechanics of Materials and Biomaterials Tuesday 04/10/07 Prof. C. Orti, MIT-DMSE I LECTURE 15: THE ELECTRICAL DOUBLE LAYER (EDL) Outline : THE ELECTRICAL DOUBLE LAYER IN BOUNDARY LUBRICATION PODCAST... REVIEW LECTURE #14 : THE ELECTRICAL DOUBLE LAYER (EDL) THE ELECTRICAL DOUBLE LAYER Solution to 1D Linearied P-B Equation For a 1:1 Monovalent Electrolyte... 4 Electrical Potential Profile for Two Interacting EDLs... 5 EDL Force Calculation (1)...6 EDL Force Calculation ()...7 Objectives: To understand the mathematical formulation for the repulsive EDL Interaction between two charged surfaces Readings: Course Reader Documents 4 and 5 Multimedia : Cartilage Podcast, Dean, et al. J. Biomech , Acknowledgement : These lecture notes were prepared with the assistance of Prof. Delphine Dean (Clemson University) 1

2 3.05 Nanomechanics of Materials and Biomaterials Tuesday 04/10/07 Prof. C. Orti, MIT-DMSE THE ELECTRICAL DOUBLE LAYER (EDL) IN BOUNDARY LUBRICATION PODCAST Courtesy of Jacob Klein. Used with permission. Source: Briscoe, W. H., et al. "Boundary Lubrication Under Water." Nature 444 (November 9, 006):

3 3.05 Nanomechanics of Materials and Biomaterials Tuesday 04/10/07 Prof. C. Orti, MIT-DMSE REVIEW LECTURE #14 : THE ELECTRICAL DOUBLE LAYER (EDL) 1 Applications, Origins of Surface Charge, Definitions : EDL, Stern layer balance between attractive ionic forces (electrical migration force) driving counterions to surface and entropy/diffusion/osmotic down the concentration gradient κd General Mathematical Form : W(D) ELECTROSTATIC = CESe C ES = electrostatic prefactor analogous to the Hamaker constant for VDW interactions κ -1 = Electrical Debye Length (characteristic decay length of the interaction)- will be defined more rigorously today Poisson-Boltmann (P-B) Formulation : ions are point charges (don't take up any volume, continuum approximation), they do not interact with each other, uniform dielectric; permittivity independent of electrical field, electroquasistatics (time varying magnetic fields are negligibly small) Stern or Helmholt layer Diffuse Layer Derived 1D P-B Equation for a 1:1 monovalent electrolyte (e.g. Na, Cl - ) ψ d Fc ε d () o Fψ() = sinh RT D 1 electrolyte (aqueous solution containing free ions) bulk ionic strength/ salt concentration D 1 >D negatively charged surface solvated coion solvated counterion bound ion ψ ( )= electrical potential R=Universal Gas Constant = J/mole K T= Temperature (K) F= Faraday Constant (96,500 Coulombs/mole electronic charge) c o (moles/cm 3 or mole/l=[m], 1 ml=1 cm 3 )=electrolyte ionic strength (IS) = bulk salt concentration, ideally for, but practically just far enough away from surface charge region, several Debye lengths away ε (C J -1 m -1 )=permittivity 3

4 3.05 Nanomechanics of Materials and Biomaterials Tuesday 04/10/07 Prof. C. Orti, MIT-DMSE SOLUTION TO 1D LINEARIZED P-B EQUATION FOR A 1:1 MONOVALENT ELECTROLYTE - For Na, Cl (monovalent 1:1 electrolyte solution) d ψ () Fco Fψ() = sinh d ε RT nd order nonlinear differential eq. solve numerically Fψ() Linearie when << 1 or ψ <~ 60 mv RT "Debye -Huckel Approximatio n" - Linearied P -B Equation d ψ () Fcψ() o = κ ψ() (*) linear differential equation d ε RT where : κ 1 = εrt F co κ Solution to (*): ψ( ) = ψ(0) e K ψ ( ) = electrical potential, K = integration constant - Boundary Conditions (1 Layer or D > 5 κ 1 ); ψ ( = ) = 0, K = 0 1) Constant Surface Potential ψ (0) = ψ = ψ = surface potential ( = 0) = constant κ -1 o s (nm) = Debye Length = the distance over which the potential decays to (1/ e) of its value at = 0, depends solely on the properties of the solution and not on the surface charge or potential -rule of thumb : range of the electrostatic interaction ~ 5 κ -1 σ ψ ο =ψ s ψ ο /e =0 POTENTIAL PROFILE Ψ() c 1 c c 3 1/κ 1 1/κ 1/κ 3 c 3 <c <c 1 "salt screening" IS [M] k -1 (nm) 10-7 (pure water) 950 [H ]=[OH - ] [NaCl] [NaCl] [NaCl] * [NaCl] [NaCl] 0.3 (not physical!) *physiological conditions 4

5 3.05 Nanomechanics of Materials and Biomaterials Tuesday 04/10/07 Prof. C. Orti, MIT-DMSE ELECTRICAL POTENTIAL PROFILE FOR TWO INTERACTING EDLs dψ ) Constant Surface Charge d = 3 σ = surface charge density (C/m ), ρ = volume charge density of entire electrolyte phase (C/m ) comes from electroneutrality : =0 σ ε d ψ dψ σ = ρd = - ε d = ε d d 0 0 Poisson's Law = ψ εκ dψ Boundary Conditions for Two Interacting Plane Parallel Laye rs : = 0, ψ = ψm for = D/ d Surface potential constant with D Surface potential changes with D (dψ/dx at surface changes with D) Φ 0 Φ ψ o ψ o =0 o ψ() Φ(x) (mv) Constant potential solution as planes are approached together Constant Charge solution when planes are approached

6 3.05 Nanomechanics of Materials and Biomaterials Tuesday 04/10/07 Prof. C. Orti, MIT-DMSE EDL : FORCE CALCULATION (1) -So now that we can solve the P-B equation and get ψ() and ρ() in space, how do we calculate a force? -We can calculate a pressure (P = force per unit area) on these infinite charged surfaces if we know the potential. Using a control box, the pressure on the surface at x = D is the pressure calculated at any point between the surfaces relative to a ground state: P( = ) - P( ) j σ ψ(x) ( ) = j ψ m = -D/ =0 = D/ control box Reference position in the bulk where: ψ() = 0 E = dψ/d = 0 c i () = c io ( ) Now at any point the pressure is going to be the sum of two terms: P( = j ) - P( ) = "electrical" "osmotic" The electrical contribution (a.k.a. Maxwell stress) is due to the electric field: ε P(= j )-P( )= (E (= i )-E ( )) "osmotic" The osmotic contribution is due to the ion concentrations (van't Hoff's Law, chemical equation of state): ε P( = j ) - P( ) = (E ( = i ) - E ( )) RT (c i( = i ) - c i( )) all ions Now some things simplify because at, E 0 and c i ( ) c io 6

7 3.05 Nanomechanics of Materials and Biomaterials Tuesday 04/10/07 Prof. C. Orti, MIT-DMSE EDL : FORCE CALCULATION (-CONT'D) -If we can simplify things if we pick j to be the point between the surfaces where E = 0 (i.e. if the surface charges are the same then this is the mid point between the two surfaces, = 0), only have an osmotic component: P( = 0) - P( ) = RT (c (0) - c ) i io all ions Note: we can pick any point j because the sum of the osmotic and electrical terms is a constant. We chose = 0 because it s less messy since we don t have to calculate E. If it s a monovalent salt solution we can plug in the formula for the concentration for Boltmann Statistics: Fψm Fψm - Fψ RT RT m P =RT ce 0 ce 0 -RTc o =RTc0 cosh -1 RT where : ψ m is the potential at =0 and P is the net force/area on the surface. If ψ m << RT/F ~60mV, then we can actually solve this equation further: Fψ m c0f ψm P RTC 0 (1- )-1 = = εκ ψ m RT RT and we can solve for ψ m if we wanted using the linearied PB equation (it s a little messy). If you plug in the value for ψ m you get: -κd P 4εκ ψ ο e (constant surface potential) 4σ -κd P e (constant surface charge) ε Exponential in this case so you can think of the Debye length, κ -1, as being the length scale over which electrostatic forces occur. 7

8 3.05 Nanomechanics of Materials and Biomaterials Tuesday 04/10/07 Prof. C. Orti, MIT-DMSE APPENDIX : MATHEMATICAL POTENTIALS FOR ELECTRICAL DOUBLE LAYER FOR DIFFERENT GEOMETRIES (From Leckband, Israelachvili, Quarterly Reviews of Biophysics, 34,, 001) Image removed due to copyright restrictions. Table in Leckband and Israelachvili, Quarterly Reviews of Biophysics, 34,, ( ) ( ψο/107) Z = tanh σ = sinh( ψ /53.4) ο c -1 J m (monovalent electrolyte) - ocm (monovalent electrolyte) 8