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Bioseparation Dr. Kamal E. M. Elkahlout Chapter 3

Bioseparation Dr. Kamal E. M. Elkahlout Chapter 3. Mass transfer. INTRODUCTION. Three types of transport phenomenae are involved in any separation process: heat transfer, fluid flow and mass transfer. Most bioseparation processes being isothermal or nearly isothermal in nature.

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Bioseparation Dr. Kamal E. M. Elkahlout Chapter 3

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  1. BioseparationDr. Kamal E. M. ElkahloutChapter 3 Mass transfer

  2. INTRODUCTION • Three types of transport phenomenae are involved in any separation process: • heat transfer, fluid flow and mass transfer. • Most bioseparationprocesses being isothermal or nearly isothermal in nature. • Role of heat transfer is not as significant as in conventional chemical separations. • The role of fluid flow is much more significant . • The role of mass transfer is the most significant . • Mass transfer deals with transport of material. • It is distinctly different from fluid flow which also deals with transport of material. • A simple example of mass transfer is the movement of a scent from one end of a room to the other.

  3. Mass transfer basically deals with transport of species within a medium or across an interface, i.e. from one medium to another. • The medium could be stationary or mobile. • There are two types of mass transfer: • 1. Purely diffusive mass transfer (or molecular diffusion) • 2. Convective mass transfer • Molecular diffusion is governed by a random walk process and involves the transport of molecules from a region of high concentration to one where its concentration is lower. • Steady state molecular diffusion of species A (e.g. sucrose) in a diffusion medium B (e.g. water) can be expressed by Fick's first law (see Fig. 3.1):

  4. Fick's first law relates the diffusive flux to the concentration under the assumption of steady state. It postulates that the flux goes from regions of high concentration to regions of low concentration, with a magnitude that is proportional to the concentration gradient (spatial derivative).

  5. Convective mass transfer takes place in flowing fluids, particularly when the flow is turbulent in nature, i.e. where there are eddies. • An equation representing steady state convective mass transfer of species A (e.g. a protein) in a transfer zone within a flowing fluid (e.g. water) is shown below (see Fig. 3.2): • Where • NA = flux of A (kg-moles/m2.s) • kA = mass transfer coefficient of A within the transfer zone (m/s) • ΔCA= concentration difference across transfer zone (kg-moles/m3)

  6. Convection is the concerted, collective movement of ensembles of molecules within fluids (i.e. liquids,gases) and rheids ( a solid material that deforms by viscous flow.). • In convective mass transfer, flux of solute takes place due to a combination of molecular diffusion and eddy diffusion. • Molecular diffusion in liquid medium • Molecular diffusion in the context of bioseparations mainly involves the transport of dissolved species in a liquid medium. • An example of this is the transport of an antibiotic from an aqueous solution to the surface of an ion-exchange resin. • Gaseous diffusion is far less important in bioseparation except in very specific types of separation e.g. freeze drying, pervaporation (Pervaporation is a membrane technical method for the separation of liquids by partial vaporization through a non-porous or porous membrane).and molecular distillation. • Molecular diffusion in liquid medium is significantly slower than that in a gaseous medium and hence the diffusion coefficients are significantly lower.

  7. If we consider a simple case of molecular diffusion e.g. amino acid (A) in water (B), the flux of the A from point 1 to 2 in the liquid medium is given by (see Fig. 3.3): • Similarly the flux of B from 2 to 1 is given by:

  8. The diffusion coefficient of A in B i.e. DAB is the same as the diffusion coefficient of B in A, i.e. DBA. • In a two-component system where the total molar concentration at any point is largely constant: • This is referred to as equimolar counter-diffusion. • This means that the molar flux of the amino in a certain direction is matched by the molar flux of water in the opposite direction.

  9. Measurement of diffusivity • A commonly used technique is based on the diffusion cell (see Fig. 3.4). • It consists of two well mixed chambers having the same volume which are separated by a porous membrane. • Initially the two chambers are filled with the liquid medium. • It is ensured that the pores of the membrane are also completely filled with the same liquid.

  10. At time t = 0, the liquid in one of the chambers (say chamber 1), is replaced with a solution of known concentration of the solute. • The concentration of the solute in one or both chambers of the diffusion cell is/are then monitored, and based on the change in solute concentration with time its diffusivity can be determined using the following equation:

  11. The superscript 0 represents initial value i.e. at t= 0.

  12. Estimation of diffusivity • The diffusivity of a solute in a liquid medium at a particular temperature can also be estimated using different mathematical correlations. • These correlations link diffusivity to solute and liquid properties such as molar volume, molecular weight and liquid viscosity. • The three most widely used correlations are: • Stokes-Einstein correlation: • where T = absolute temperature (K) • μ = viscosity of the liquid medium (kg/m s) • VA = solute molar volume at its normal boiling point (m3/kg-mole)

  13. Wilke-Chang correlation: • Where (ɸ) = association parameter (-) and has a value of 2.6 for water • MB = molecular weight of the liquid medium (kg/kg-mole). • Polson correlation: • Where MA = molecular weight of the solute (kg/kg-mole).

  14. Diffusivity of electrolytes can be estimated using the Nernst-Haskell correlation: • Where • n+ = valency of the cation • n- = valency of the anion • λ+ = ionic conductance of the cation • λ- = ionic conductance of the anion

  15. The correlation shown above gives diffusivity in cm2/s. • λ and n values for different cations and anions can be obtained from standard tables of physical properties. • The diffusion concepts discussed so far are based on simple systems, i.e. the solution of a single solute. • Most systems handled in bioseparation processes are complex and hence the correlations discussed above have to be appropriately modified to account for specific system related effects.

  16. Example 3.1 • Estimate the diffusivity of the protein lysozyme in water at 25 degrees centigrade. • Solution • The diffusivity of a solute can be calculated from its molecular weight using Polson correlation i.e. equation (3.10). • From Table 2.2 the molecular weight of lysozyme is 14,100 kg/kg-mole. • The viscosity of water at 25 degrees centigrade is 0.001 kg/m s. Therefore:

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