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2.7 Diffusivity in Solids and its Applications 
In many processes such as drying, adsorption and membrane separations require the contact of gases or liquids with solids. Diffusion occurs in these cases in the solid phase and the diffusion mechanism is not as simple as in the case of gases or liquids. However, it is possible to describe by the Fick‟s law used in the case of fluids. If the diffusivity is independent of concentration and there is no bulk flow, the steady state molar flux (NA) in the Z direction is given by Fick‟s law as follows:
Diffusivity In Solids And Its Applications | Mass Transfer - Chemical Engineering                                      (2.76)
where DA is the diffusivity of A through the solid. Integration of the above Equation gives diffusion through a flat slab of thickness z:
Diffusivity In Solids And Its Applications | Mass Transfer - Chemical Engineering                           (2.77)
where CA1 and CA2 are the concentrations at two opposite sides of the slab. This is similar expression for diffusion obtained for fluids under identical situation. For other solid shapes the general Equation for rate of diffusion (w) is
Diffusivity In Solids And Its Applications | Mass Transfer - Chemical Engineering             (2.78)

where Sav is the average cross section for diffusion.

2.7.1 Mechanism of diffusion in solids and its application
The diffusion of solutes through the solids plays an important role in many processes such as heterogeneous catalytic reactions. The structure of solid and interaction with the solutes are important for the rate of diffusion. 
(a) Diffusion in porous solids 
The solid sometimes may act as porous barrier or as porous catalyst pellets and is normally surrounded by a single body of fluid. The inward or outward movement of the solutes through the pores of the solid is mainly by diffusion. This movement may occur inside the pore or at the surface of the adsorbed solute.

(b) Diffusion inside pore
At low pressure the mean free path of the molecules may be larger than the diameter of the passage when the diffusion occurs inside the fine pores of the solid. The collision with wall becomes important compared to collision among molecules. The diffusion of this kind is known as „Knudsen diffusion‟. To quantify Kundsen diffusivity a simple Equation based on kinetic theory of gases was proposed as follows:
Diffusivity In Solids And Its Applications | Mass Transfer - Chemical Engineering                                  (2.79)
where rp radius of passage and v is the average velocity of the molecules due to their thermal energy which is defined as
Diffusivity In Solids And Its Applications | Mass Transfer - Chemical Engineering                                   (2.80)
Here T is the temperature in K and M is the molecular weight. The flux due to Knudsen diffusion is similar to Fick‟s law:
Diffusivity In Solids And Its Applications | Mass Transfer - Chemical Engineering       (2.81)

(c) Surface diffusion
The diffusion of adsorbed molecules on the surface due to concentration gradient is kwon as surface diffusion. If the fractional coverage of the surface is less than unity then the some of the active sites remain empty. Adsorbed molecule having energy greater than the energy barrier tends to migrate to an adjacent vacant site. This migration is visualized to occur by „hoping‟ mechanism. The flux due to surface diffusion may be written similar to Fick‟s law:
Diffusivity In Solids And Its Applications | Mass Transfer - Chemical Engineering                                (2.82)
where Ds is the surface diffusion coefficient (m2/s) and Cs is the surface concentration of the adsorbed molecules (kmol/m2 ). Js is the number of moles transported across unit distance on the surface normal to the direction of transport (kmol/m.s).

(d) Diffusion through polymers
The diffusion of solutes through polymeric solids is more like diffusion in liquids, particularly for the permanent gases. The gas dissolves into the solid exposed to the gas and usually described by Henry‟s law. The gas then diffuses from high to low pressure side. Hence, high pressure is applied to increase gas concentrations, thus increasing respective solubility (difference in solubility is the key feature) of gases. The polymeric chains are in a state of constant thermal motion and diffusing molecule move from one location to the adjacent location due to the potential barrier. An Arrhenius type Equation may be applied for the temperature dependency of the diffusion coefficient in polymers. Diffusivity In Solids And Its Applications | Mass Transfer - Chemical Engineering                               (2.83)
where HD is the energy of activation and D0 is a constant. For the permanent gases the typical diffusivity value is in the order of 10-10 m2/s.

Example Problem 2.1:
A test tube, 1.5 cm in diameter and 18 cm long, has 0.4 gm camphor (C10H16O) in it. How long will it take for camphor to disappear? The pressure is atmospheric and temperature is 200C. The sublimation pressure of camphor at this temperature is 97.5 mm Hg; diffusivity of camphor can be estimated by using Fuller‟s Equation:
Diffusivity In Solids And Its Applications | Mass Transfer - Chemical Engineering  
where, T in K; P in bar, MA, MB are molecular weights of A and B, respectively.
Diffusivity In Solids And Its Applications | Mass Transfer - Chemical Engineering

Solution2.1:
MA=152.128,
MB=28.9,
T=293K,
P=1.013 bar (1atm) 
Diffusivity In Solids And Its Applications | Mass Transfer - Chemical Engineering
DAB=5.644�10-6 m2/s
pAo = 97.5 mmHg =0.1299 bar
pA1 = 0 bar
/=12 cm=0.12 m
Diffusivity In Solids And Its Applications | Mass Transfer - Chemical Engineering
=5.539�104s
t =15.39 hr

Example Problem 2.2: 
A mixture of He and N2 gas is contained in a pipe at 250C and 1 atm. total pressure which is constant throughout. At one end of the pipe, partial pressure of He is 0.6 atm. and at the other end (0.2 m) it is 0.2 atm. Calculate the steady state flux of He if DAB of He-N2 mixture can be estimated by using Fuller‟s Equation with
∑v=2.88m/s; and ∑vB =17.9m/s.

Solution 2.2: 
Diffusivity In Solids And Its Applications | Mass Transfer - Chemical Engineering
DAB=7.035�10-5 m2/s
pA0 = 0.6 atm
pA1 = 0.2 atm
/=0.2 m
T=298K 
Diffusivity In Solids And Its Applications | Mass Transfer - Chemical Engineering
=5.68�10-6 k mol/m2.s

Example Problem 2.3: MeOH (A) is separated from aqueous solution by distillation. At a section of column, vapor phase contains 0.76 mole fraction MeOH and liquid phase has 0.6 mole fraction. Temperature of the section is 71.20C and total pressure is 1 atm. throughout 1 mm thick vapor film. If molar latent heat of vaporization of MeOH is 8787 K Cal/K mol and that of water (B) is 10039 K Cal/K mol at the given temperature. Calculate MeOH and water vapor flux.
Given: If mole fraction of MeOH in liquid is 0.6, equilibrium vapor will be 0.825. Vapor phase diffusivity of MeOH, DAB=1.816�10-5 m2/s.

Solution 2.3:
Diffusivity In Solids And Its Applications | Mass Transfer - Chemical Engineering
NA∆HA = - NB∆HB
NA�8787 = -NB�10039 
Diffusivity In Solids And Its Applications | Mass Transfer - Chemical Engineering
NB=-0.8753NA
Given data,
DAB=1.816 �10-5 m2/s,
P=1 atm,
R=0.0823 m3atm/kmol
T=344.2 K,
/=1�10-3 m,
yA0=0.825,
yA1=0.76
We have,
Diffusivity In Solids And Its Applications | Mass Transfer - Chemical Engineering
=4.65�10-5 k mol/m2.s
NB=-0.8753�4.65�10-5 k mol/m2.s
=-4.07�10-5 k mol/m2.s

The document Diffusivity In Solids And Its Applications | Mass Transfer - Chemical Engineering is a part of the Chemical Engineering Course Mass Transfer.
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FAQs on Diffusivity In Solids And Its Applications - Mass Transfer - Chemical Engineering

1. What is diffusivity in solids and why is it important in chemical engineering?
Ans. Diffusivity in solids refers to the ability of a substance to move or spread out within a solid material. It is an important property in chemical engineering as it determines how quickly a substance can diffuse through a solid, which is crucial for various processes such as mass transfer, heat transfer, and reaction kinetics.
2. How is diffusivity in solids calculated and what factors affect it?
Ans. Diffusivity in solids can be calculated using Fick's laws of diffusion. The diffusivity coefficient (D) is determined by dividing the diffusion flux (J) by the concentration gradient (dC/dx) and the cross-sectional area (A) of the material, as D = J / (dC/dx * A). Factors that affect diffusivity in solids include temperature, composition of the solid, porosity, and presence of defects or impurities.
3. What are some common applications of diffusivity in solids in chemical engineering?
Ans. Diffusivity in solids has various applications in chemical engineering, including the design and optimization of catalysts, the development of materials for energy storage, the modeling of drug release from pharmaceutical formulations, and the understanding of corrosion processes in metals. It is also important in the fabrication of semiconductors and the diffusion of dopants in microelectronics.
4. How can diffusivity in solids be experimentally measured?
Ans. Diffusivity in solids can be experimentally measured using techniques such as steady-state diffusion, transient diffusion, and impedance spectroscopy. These methods involve measuring the concentration profile or the time-dependent diffusion behavior of a substance within a solid material. In some cases, mathematical models and simulations are used to estimate diffusivity based on experimental data.
5. What challenges are associated with measuring diffusivity in solids and how can they be overcome?
Ans. Measuring diffusivity in solids can be challenging due to factors such as the complexity of the material structure, the need for accurate and sensitive measurement techniques, and the influence of other transport mechanisms like convection or surface reactions. These challenges can be overcome by carefully selecting appropriate experimental conditions, using advanced characterization techniques such as electron microscopy or spectroscopy, and validating the results through multiple measurements or simulations.
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