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Chapter 5 Diffusion Skip Sec. 5-7, 5-8 and 5-9.
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Homework No. 6 Problems 4-17, 4-19, 4-32, 4-47, 4-48, 5-9, 5-15, 5- 23, 5-26, 5-60
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The levels of atomic arrangement in materials: (a) Inert gases have no regular ordering of atoms. (b, c) Some materials, including steam and glass, have ordering only over a short distance (d) Metals and many other solids have a regular ordering of atoms that extends through the material.
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Introduction Difference between liquid-state and solid –state diffusion is the slower diffusion rate in the solid. Tight atomic structure of atoms has an impact on the diffusion of atoms or ions within the solid. The energy requirements to squeeze most atoms or ions through a perfect crystal structure are so high that diffusion is nearly impossible.
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Vacancy Diffusion What is needed to make solid-state diffusion practical? POINT DEFECTS!!! V
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Vacancy Diffusion atom interchange from a normal lattice position to an adjacent vacant lattice site. the extent of vacancy diffusion is controlled by the concentration of these defects. the direction of vacancy motion is opposite to direction of diffusing atoms. both self-diffusion and interdiffusion occur by this mechanism.
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Diffusion Concepts processes reactions in solid state occur by spontaneous rearrangement of atoms into a more stable state. for reactions to proceed from an unreacted to a reacted state, atoms must have enough energy to overcome an activation energy barrier.
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Diffusion Concepts Stepwise migration of atoms from a lattice point to another. In a solid material atoms are in constant motion. Conditions for atom migration: empty adjacent site. atom must have enough energy to break bonds and cause lattice distortion during displacement. diffusive motion influenced by atom vibrational energies f(T)
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Interstitial Diffusion migration of interstitial atoms from and interstitial position to adjacent empty one. Typical interstitial atoms: hydrogen, carbon, nitrogen, and oxygen. In most metals interstitial diffusion occurs much more rapidly than vacancy diffusion.
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Activation Energy for Diffusion a diffusing atom must squeeze past neighbor atoms to reach new site. Energy must be supplied to force atom to its new position activation energy, Q. normally less energy is required to squeeze an interstitial atom past the surrounding atoms.
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Steady State Diffusion Flux: # of atoms passing through a plane of unit area per unit time. diffusion is a time-dependent process. the mass transfer rate is often needed. mass transfer = diffusion flux (J) (kg/m2·s; atoms/ m2·s)
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C1C1 C2C2 x1x1 x2x2 C X J Let the solute concentration be C 1 at point x 1 and C 2 at point x 2. The concentration gradient is since C 2 < C 1.
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Fick’s First Law
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D is called the diffusivity or the diffusion coefficient.
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where X = probability that an atom moves, Q = activation energy per mole, E = activation energy per atom, T = temperature in K. 1 0 X T
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Factors Influencing Diffusion Diffusing Species: the magnitude of the diffusion coefficient D is indicative of the rate at which atoms diffuse. temperature has a profound effect on diffusion rates:
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DoDo D T
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log D o log D 0 The plot of log D vs. 1/T is a straight line of slope = The intercept of this line with the log D axis is log D o at
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Diffusion Example: Determine D cu in Ni at 500°C. Q d = 256 kJ/mol D O = 2.7 x 10 - 5 m 2 /sec T = 500 + 273 = 773 K R = 8.31 J/mol-K D = 1.33 x 10 -22 m 2 /sec
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Factors Influencing Diffusion Arrhenius plot of relationship between diffusion coefficient and reciprocal of temperature for different elements.
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Activation Energy for Diffusion
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Factors Influencing Diffusion Diffusing Species: The crystal structure of the metal affects the diffusion rate: Diffusivities of different elements in BCC-Fe are higher than in FCC-Fe at the same temperature (e.g. 910ºC). Reasons for faster diffusion in BCC compared with FCC iron: BCC iron lattice is slightly more open; it has lower packing factor than FCC. BCC lattice has a coordination number of 8 compared with 12 in FCC fewer bonds must be broken when elements diffuse in BCC iron. G.F. Carter. “Principles of Physical & Chemical Metallurgy”. American Society for Metals (1979)
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Non-steady State Diffusion (Fick’s Second Law – not covered) steady-state diffusion not commonly encountered in engineering materials. in most cases the concentration of solute atoms at any point in the material changes with time non-steady state diffusion. t1t1 t2t2 t0t0
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Factors Influencing Diffusion Diffusion is faster along grain boundaries than through grains: More open structure at grain boundaries than the interior grain. Much lower activation energy for diffusion in grain boundaries compared transgranular diffusion. G.F. Carter. “Principles of Physical & Chemical Metallurgy”. American Society for Metals (1979).
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Grain boundary Volume log D 1/T Since Q gb < Q v, the slope of the Arrhenius plot is less steep for the part of D due to grain boundary diffusion than for the part of D due to volume diffusion.
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1/T log D Coarse-grained Fine-grained
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