Modeling of straight jet dynamics in electrospinning of polymer nanofibers

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Modeling of straight jet dynamics in electrospinning of polymer nanofibers Rohan Pandya 1, Kumar Akash 2, Venkataramana Runkana 1 1 Tata Research Development and Design Centre, Tata Consultancy Services, Pune 2 Department of Chemical Engineering, Indian Institute of Technology, Delhi 1

Introduction Nanofibers are produced by solidification of a polymer solution stretched by an electric field. Properties: High surface area per unit mass, Very high porosity, Layer thinness, High permeability, Low basic weight, Applications: wound dressing, drug or gene delivery vehicles, biosensors, fuel cell membranes and electronics, tissue-engineering processes. Mathematical modeling in electrospinning process of nanofibers: a detailed review- S. Rafiei, S. Maghsoodloo, B. Noroozi, Mottaghitalab and A. K. Haghi(2012) 2

Objective Build a mathematical model to predict the radius of a straight jet electrospinning process. Validate the model for Newtonian fluid Non Newtonian fluid Viscoelastic fluid Study the dependence of radius on various working parameters. 3

Basic Assumptions Slender body theory R z z 1/4 R + 4zR = 0 Leaky dielectric model Free charge which accumulates on the interface modifies the field. Viscous flow develops - stresses balance the tangential components of the field acting on interface charge Laminar flow Electric field inside the fibre is being solved D. A. Saville, Electrohydrodynamics: The Taylor-Melcher Leaky Dielectric Model 4

Mathematical Model Mass conservation equation: πr 2 v = Q charge conservation equation: πr 2 KE + 2πRvσ = I Electric Field equation: E z = E z lnχ( 1 ε Momentum Equation: d(πr2 ρv 2 ) dz d σr dz β 2 = πr 2 ρg + d[πr2 p+τ zz ] dz d 2 ER 2 dz 2 ) + γ R 2πRR + 2πR(t t e t n e R ) J.J. Feng, Phys. Fluids 14 (2002) 3912 3926 5

Scaling Characteristic Scales Length: R 0 Velocity: v 0 = Q/( ρ R 2 0 ) Electric field: E 0 =I/( ρ R 2 0 K) Surface charge density: σ 0 = ε E 0 Stress: τ 0 = η 0 v 0 / R 0 6

Mathematical Model (non-dimensional) Mass conservation equation: R 2 v = 1 Charge conservation equation: ER 2 + PeRvσ = 1 Electric Field equation: d σr E = E lnχ( dz Momentum Equation: vv = 1 Fr + T ReR 2 + β 2 d 2 ER 2 dz 2 ) R + WeR 2 ε(σσ + βee + 2Eσ ) R Tensile Force, T = 3ηR 2 v, for Newtonian and Non- Newtonian T = T p + 3η(1 r η )R 2 v, for viscoelastic fluids. 7

Polymer Stress Tensor Equation (Giesekus viscoelastic fluid) τ prr + λ(vτ prr + v τ prr) + α λ τ 2 η prr = η p v p τ pzz + λ(vτ pzz 2v τ pzz) + α λ τ 2 η pzz = 2η p v p Non-dimensionalised form τ prr + De(vτ prr + v τ prr) + α De τ 2 η prr = r η v p τ pzz + De(vτ pzz 2v τ prr) + α De η p τ pzz 2 = 2r η v 8

Boundary Conditions Model is solved for 1-D geometry R is converted to v using the mass balance equation and then solved τ prr = 2r η R R 3 τ pzz = 2τ prr Mathematics ODE solver is used A Model for Electrospinning Viscoelastic Fluids, P.C. Roozemond, 0576690 Report No. MT07.12 9

Results Experimental data of Hohman et al. for a glycerol jet R0=0.08 cm, L=56 cm, Q=1 ml/min, E = 5 kv/cm, I=170 na, kinematic viscosity=514.9 cm2/s, K=50.01 ms/cm The parameters of Hohman et al.: X=75, Β=45.5, Re=4.451*10-3, We=1.099*10-3, Fr=8.755*10-3, Pe=1.835310-4, ε=0.7311, E =5.914, K=0.01 µs/cm. C) All parameters as above with a higher conductivity K=4.8*10-6 S/m, corresponding to Pe=3.823*10-5, ε=3.173*10-2, and E =28.32. Hohman et al, Electrospinning and electrically forced jets: II. Applications, Phys. Fluids 13, 2221 (2001). 10

Giesekus model - Validation against Experimental Data Experimental data of Doshi et al. for a 4% PEO solution compared against our model. Electric field (E = 40 kvm 1) Nozzle radius (R0 = 45 m) length of the straight jet (L = 30 mm). The density ρ = 1.2 103 kgm 3 dielectric constant, ε / ε = 42.7 Viscosity, η0 = 12.5 P; surface tension, γ = 76.6 dyn cm 1 Conductivity, K = 4.902 10 3 Ω 1 m 1. The solvent viscosity is ηs = 10 2 poise for water I = 0.12 A Q = 10 μl min 1. Doshi et al, Electrospinning and applications of electrospun fibers, J. Electrostat. 35 (1995) 151 160 11

Giesekus Model-Variation with viscosity ratio (r η ) Radius vs z 12

Giesekus Model-Variation with volumetric flow rate (Q) 13

Conclusion A mathematical model was built and validated against experimental data for Newtonian jet and Feng s model for Non- Newtonian jets. The model was validated against experimental data for Giesekus model and extended to Oldroyd-B model. The model was extended for polymer solution with Non- Newtonian solvent. The dependence of the process on different working and material parameters was studied. 14

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