To determine To calculate: The study state distribution of compound A from x = 0 to L + L f , by using the finite-difference method, apply cantered finite differences with Δ x = 0.001 cm . Explanation Given Information: A biofilm grows on the surface of a solid refer to the Figure P28.13, in the Fig. P28.13 L f ( cm ) is the thickness of the biofilm, and L ( cm ) is the diffusion layer. The chemical compound A , which diffuses into the biofilm with an irreversible first-order reaction which converts it to a product B . The ordinary differential equations for compound A by using Steady-state mass balance is, D d 2 c a d x 2 = 0 0 ≤ x < L D f d 2 c a d x 2 − k c a = 0 L ≤ x < L + L f Here, D is the diffusion co-efficient in the diffusion layer which is 0. 8 cm 2 /d , D f is the diffusion co-efficient in the biofilm which is 0.64 cm 2 /d , and k is the first-order rate for the conversion of A to B which is 0.1 / d . Hold the following boundary conditions. c a = c a 0 at x = 0 d c a d x = 0 at x = L + L f Here, c a 0 is the concentration of A in the bulk liquid which is 100 mol/L , L = 0.008 cm , and L f = 0.004 cm . Δ x = 0.001 cm Formula used: The finite divided difference formula is, f ″ ( x 0 ) = c i − 1 − 2 c i + c i + 1 Δ x 2 Calculation: Recall the ordinary differential equations for compound A , D d 2 c a d x 2 = 0 0 ≤ x < L D f d 2 c a d x 2 − k c a = 0 L ≤ x < L + L f Substitute the finite divided difference formula in the above differential equations. D ( c a , i − 1 − 2 c a , i + c a , i + 1 Δ x 2 ) = 0 0 ≤ x < L D f ( c a , i − 1 − 2 c a , i + c a , i + 1 Δ x 2 ) − k c a , i = 0 L ≤ x < L + L f Expand the terms in the above equations. − D Δ x 2 c a , i − 1 + 2 D Δ x 2 c a , i − D Δ x 2 c a , i + 1 = 0 0 ≤ x < L − D f Δ x 2 c a , i − 1 + ( 2 D f Δ x 2 + k ) c a , i − D f Δ x 2 c a , i + 1 = 0 L ≤ x < L + L f …… (1) Apply the boundary condition for the first node ( i = 1 ) . 2 D Δ x 2 c a , 1 − D Δ x 2 c a , 2 = D Δ x 2 c a , 0 …… (2) Apply the boundary condition for the last node ( i = n ) . − 2 D f Δ x 2 c a , n − 1 + ( 2 D f Δ x 2 + k ) c a , n = 0 …… (3) Now required s special equation at the interface between the diffusion layer and the biofilm x = L . Write a flux balance around this node as, D c a , i − 1 − c a , i Δ x + D f c a , i + 1 − c a , i Δ x − k Δ x 2 c a , i = 0 Separating the terms, − D Δ x c a , i − 1 + ( D + D f Δ x + k Δ x 2 ) c a , i − D f Δ x c a , i + 1 = 0 Substitute 0. 8 cm 2 /d for D , 0.001 cm for Δ x , 100 mol/L for c a , 0 in equation (2), yield unit for First node. 2 ( 0. 8 ) ( 0.001 ) 2 c a , 1 − ( 0. 8 ) ( 0.001 ) 2 c a , 2 = 0. 8 ( 0.001 ) 2 ( 100 ) 1600000 c a , 1 − 800000 c a , 2 = 80000000 16 c a , 1 − 8 c a , 2 = 800 For interior nodes (diffusion layer), Substitute 0

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Chapter 28, Problem 13P

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To calculate: The study state distribution of compound A from x=0 to L+Lf, by using the finite-difference method, apply cantered finite differences with Δx=0.001 cm.

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Chapter 28 Solutions

Numerical Methods for Engineers

Ch. 28 - 8.1 Perform the first computation in Sec. 28.1,...Ch. 28 - 28.2 Perform the second computation in Sec. 28.1,...Ch. 28 - A mass balance for a chemical in a completely...Ch. 28 - 28.4 If, calculate the outflow concentration of a...Ch. 28 - 28.5 Seawater with a concentration of 8000 g/m3...Ch. 28 - 28.6 A spherical ice cube (an “ice sphere”) that...Ch. 28 - The following equations define the concentrations...Ch. 28 - 28.8 Compound A diffuses through a 4-cm-long tube...Ch. 28 - In the investigation of a homicide or accidental...Ch. 28 - The reaction AB takes place in two reactors in...

Ch. 28 - An on is other malbatchre actor can be described...Ch. 28 - The following system is a classic example of stiff...Ch. 28 - 28.13 A biofilm with a thickness grows on the...Ch. 28 - 28.14 The following differential equation...Ch. 28 - Prob. 15P Ch. 28 - 28.16 Bacteria growing in a batch reactor utilize...Ch. 28 - 28.17 Perform the same computation for the...Ch. 28 - Perform the same computation for the Lorenz...Ch. 28 - The following equation can be used to model the...Ch. 28 - Perform the same computation as in Prob. 28.19,...Ch. 28 - 28.21 An environmental engineer is interested in...Ch. 28 - 28.22 Population-growth dynamics are important in...Ch. 28 - 28.23 Although the model in Prob. 28.22 works...Ch. 28 - 28.25 A cable is hanging from two supports at A...Ch. 28 - 28.26 The basic differential equation of the...Ch. 28 - 28.27 The basic differential equation of the...Ch. 28 - A pond drains through a pipe, as shown in Fig....Ch. 28 - 28.29 Engineers and scientists use mass-spring...Ch. 28 - Under a number of simplifying assumptions, the...Ch. 28 - 28.31 In Prob. 28.30, a linearized groundwater...Ch. 28 - The Lotka-Volterra equations described in Sec....Ch. 28 - The growth of floating, unicellular algae below a...Ch. 28 - 28.34 The following ODEs have been proposed as a...Ch. 28 - 28.35 Perform the same computation as in the first...Ch. 28 - Solve the ODE in the first part of Sec. 8.3 from...Ch. 28 - 28.37 For a simple RL circuit, Kirchhoff’s voltage...Ch. 28 - In contrast to Prob. 28.37, real resistors may not...Ch. 28 - 28.39 Develop an eigenvalue problem for an LC...Ch. 28 - 28.40 Just as Fourier’s law and the heat balance...Ch. 28 - 28.41 Perform the same computation as in Sec....Ch. 28 - 28.42 The rate of cooling of a body can be...Ch. 28 - The rate of heat flow (conduction) between two...Ch. 28 - Repeat the falling parachutist problem (Example...Ch. 28 - 28.45 Suppose that, after falling for 13 s, the...Ch. 28 - 28.46 The following ordinary differential equation...Ch. 28 - 28.47 A forced damped spring-mass system (Fig....Ch. 28 - 28.48 The temperature distribution in a tapered...Ch. 28 - 28.49 The dynamics of a forced spring-mass-damper...Ch. 28 - The differential equation for the velocity of a...Ch. 28 - 28.51 Two masses are attached to a wall by linear...

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