Mass Transport in Solids and FluidsCambridge University Press, 2 lis 2000 The field of matter transport is central to understanding the processing of materials and their subsequent mechanical properties. While thermodynamics determines the final state of a material system, it is the kinetics of mass transport that governs how it gets there. This book, first published in 2000, gives a solid grounding in the principles of matter transport and their application to a range of engineering problems. The author develops a unified treatment of mass transport applicable to both solids and liquids. Traditionally matter transport in fluids is considered as an extension of heat transfer and can appear to have little relationship to diffusion in solids. This unified approach clearly makes the connection between these important fields. This book is aimed at advanced undergraduate and beginning graduate students of materials science and engineering and related disciplines. It contains numerous worked examples and unsolved problems. The material can be covered in a one semester course. |
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... alloys D. I. Bower and W. F. Maddams The vibrational spectroscopy of polymers J. Zarzycki Glasses andthevitreousstate R. A. Street Hydrogenated amorphous silicon T.W. Chou Microstructural design of fiber composites A. M. Donald and A.
... alloys D. I. Bower and W. F. Maddams The vibrational spectroscopy of polymers J. Zarzycki Glasses andthevitreousstate R. A. Street Hydrogenated amorphous silicon T.W. Chou Microstructural design of fiber composites A. M. Donald and A.
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... alloy duringinsituannealing within the electron microscope at 320°C. These twomicrographs, taken15minutesapart, show the progressive dissolution of platelike particles of CuAl 2 .The field of each micrograph is about 4 μm wide ...
... alloy duringinsituannealing within the electron microscope at 320°C. These twomicrographs, taken15minutesapart, show the progressive dissolution of platelike particles of CuAl 2 .The field of each micrograph is about 4 μm wide ...
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... alloys 2 Steadystate diffusion 2.1 Fick's FirstLaw 2.2 Applications to steadystate problems 2.2.1 Measurement of the diffusion coefficient 2.2.2 Permeability of gasesthrough a solid 2.2.3 Diffusion inparallel through a composite solid ...
... alloys 2 Steadystate diffusion 2.1 Fick's FirstLaw 2.2 Applications to steadystate problems 2.2.1 Measurement of the diffusion coefficient 2.2.2 Permeability of gasesthrough a solid 2.2.3 Diffusion inparallel through a composite solid ...
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... alloys 6.1 Introduction 6.2 Changing temperature within a twophase field 6.2.1 Solution valid at short time 6.2.2 Solution validat long time 6.3 Particle dissolution 6.3.1 Dissolution of plates 6.3.2 Dissolution ofspherical particles ...
... alloys 6.1 Introduction 6.2 Changing temperature within a twophase field 6.2.1 Solution valid at short time 6.2.2 Solution validat long time 6.3 Particle dissolution 6.3.1 Dissolution of plates 6.3.2 Dissolution ofspherical particles ...
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... alloys 7.6 Further reading 7.7 Problems tochapter7 8 Mass transport inthe presence of convection 8.1 Transient diffusion in fluids 8.2 Mass transportat aflowing interface 8.3 Mass transfercoefficient 8.3.1 Mass transfer to spheres 8.3.2 ...
... alloys 7.6 Further reading 7.7 Problems tochapter7 8 Mass transport inthe presence of convection 8.1 Transient diffusion in fluids 8.2 Mass transportat aflowing interface 8.3 Mass transfercoefficient 8.3.1 Mass transfer to spheres 8.3.2 ...
Spis treści
Transient diffusion problems | |
concentration Cs 3 6 2 Uniform initial | |
materials engineering | |
Applications involving | |
Heat treatmentofbinary alloys | |
Diffusion in concentrated alloysand fluids | |
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activation energy alloy annealed assume assumptions Atomic Percent boundary conditions calculate carbon cementite composition concentration gradient concentration profile consider convection copper crosssectional cylinder density determine developed diameter diffusion coefficient diffusion couple diffusion distance diffusion problems diffusive flux dissolved equal equalto equation equilibrium constant error function eutectoid evaporation example Fick’s First Law Fick’s Second Law Figure film fixed flow fluid fraction free energy geometry given grain boundary growth heat hydrogen initial conditions interdiffusion interstitial inthe involving kinetics lattice layer liquid mass transfer coefficient masstransfer material metal molar molar volume molten nickel nitrogen occurs ofthe oxidation oxygen parameter particles pearlite phase diagram plate precipitate pressure radioactive reaction result schematic illustration solid solubility solute concentration species sphere spherical steel substitute Suppose surface concentration temperature thatthe thediffusion thickness tothe vapour velocity vessel volume wecan Weight Percent zero