A droplet of liquid A of radius r₁ is suspended in a stream of gas B shown below. Gas film We postulate that there is a spherical, stagnant film of radius r2 surrounding the droplet. The concentration of A in the gas phase is XA₁ at r = r₁ and XA2 at the outer edge of the film r = r (a) Use conservation of mass to show that the flux of species A in the gas film is: 1 d r² dr :(r² NA,r): 0 = Is the flux constant throughout the film? Why or why not? (Think about geometry.) (b) Use the expression for the molar flux NA,r (including convection and diffusive terms) show that the concentration profile in the film satisfies the following differential equation: d 1- (r² d - [In(1 − x₁)]) = State the boundary conditions. Do not attempt to solve the ODE. r² dr dr = 0

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A droplet of liquid A of radius r₁ is suspended in a stream of gas B shown below. Gas film We postulate that there is a spherical, stagnant film of radius 1₂ surrounding the droplet. The concentration of A in the gas phase is XA₁ at r = ₁ and XÃ2 at the outer edge of the film r = r₂. (a) Use conservation of mass to show that the flux of species A in the gas film is: 1 d r² dr (r² N₁,r) = 0 Is the flux constant throughout the film? Why or why not? (Think about geometry.) (b) Use the expression for the molar flux NA,r (including convection and diffusive terms) to show that the concentration profile in the film satisfies the following differential equation: 1 d (r² = [In(1-x₂)]): dr State the boundary conditions. Do not attempt to solve the ODE. =