Nirmal K. Sinha

Engineering Physics of High-Temperature Materials


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considered as “cold.” Water temperature of +50 °C may be considered as “warm,” but any human body temperature of 40 °C is considered as rather “high” and feverish because the body temperature of about +37 °C is considered as “normal” for a human. These definitions for temperatures were convenient and extended to materials in general. Materials at temperatures greater than say 70 °C may be considered as “high temperature” for human safety. In this way, the title of this book may be misleading. For materials science and engineering, the definition of high temperature has to be based on the state of the solid material under scrutiny.

      The solid state is also subject to question. We will, of course, generally avoid solids, like polymers, in order to simplify the scope of this book. Ordinary glass is a solid with amorphous structure, but it could, phenomenologically speaking, deform like crystalline materials as temperature rises. Some rationalization can be made with glass because its structure may not show a long‐range order, but may have crystal‐like nanoscale structure. The primary issue then is how to characterize the thermal states of crystalline solids in general and relate them to all natural, ice and rocks, and fabricated materials, metals, and alloys.

      As for metallic alloys, in many sections of this book, we will concentrate on engineering properties of titanium‐base and nickel‐base superalloys due to the availability of relevant experimental results obtained directly by the authors of this book. These alloys are more complex than any metallic alloys being used today. Many metallurgists consider them as the most fascinating of all metallic alloys and they are mostly used for the hottest parts of gas turbine engines. Actually, their use encompasses the highest homologous temperature of any common alloy system (Ross and Sims 1987).

      Sea‐Level Change

      GLACIAL MELTING

      EARTH'S RESPONSE

      TECTONIC PROCESSES

      Depending on the location on Earth's surface, there are three main processes that govern the rise and fall of sea level relative to the crust. These are (i) the melting histories of ice sheets, (ii) the mechanical response of Earth's plates to the redistributed surface load of ice and meltwater, and (iii) tectonic processes causing uplift or subsidence of shorelines.

      Uses of Sea‐Level Changes

      GLACIOLOGISTS

      TECTONOPHYSICISTS

      GEOPHYSICISTS

      Nakada and Lambeck (1987) also pointed out three different disciplines with different approaches to examine and use the changes in sea level that occurred during the Holocene period: “Glaciologists have used the sea‐level information to constrain the volume of past ice sheets; tectonophysicists use the relative sea‐level changes to examine the processes that deform the crust and lithosphere; geophysicists use the sea‐level signatures to estimate the rheological properties of the mantle and the mechanical properties of the lithosphere.”

      1.6.1 Issues with Terminology: Elastic, Plastic, and Viscous Deformation

      The deformation in a crystalline material consists of two major parts – an elastic part associated with the recoverable distortions of its atomic lattice structure, and an inelastic part. The term “inelastic” is associated with the part of the deformation that is “really a deviation” from the time‐independent (isothermal) elastic response. In classical materials science literature and for ordinary temperatures (less than 0.2 T m, where T m is the melting point in kelvin), the inelastic deformation is assumed (by default) to be time independent and is commonly referred to as “plastic.” However, experimental evidence tends to indicate that the classically described inelastic part actually includes a time‐dependent recoverable portion, called anelastic or delayed elastic strain. This portion is more observable as temperature increases.

      Experimental and theoretical concepts of time‐independent plastic deformation and the large volume of associated literature involving various yield functions, yield surfaces, envelopes, etc. have become the backbone for many engineering practices. These developments occurred before our knowledge of crystalline defects, particularly lattice vacancies (point defects) and dislocations (line defects) and their dynamics, broadened our understanding of microstructure‐sensitive micromechanical processes of failure in engineering materials. For historical reasons, the literature is still not clear about the exact definition of the term “plastic.” There are confusions between the classical “rate‐insensitive” or “time‐independent” plasticity (which is physically impossible because crystalline defects take time to move) and time‐dependent, rate‐sensitive flow, called “creep,” often treated as independent mechanisms. Moreover, the term “plastic” usually lumps together the permanent and the time‐dependent and hence rate‐sensitive recoverable anelastic or delayed elastic component of deformation readily observed at temperatures >0.3 T m.

      In this book, we try to avoid the term “plastic” and associated terms, like “viscoplasticity,” and others. We will use the term “viscous” for any permanent deformation. Viscous deformation provides a measure of irreversible changes in the structure of the material. This name is consistent with the term “viscoelastic,” irrespective of stress‐wise “linear” or “nonlinear” viscoelasticity (known as power‐law creep). Unfortunately, the use of the term “viscoelasticity,” because of historical usage in association with classical plasticity, may lead one to think of only linear stress dependency. We realize that the use of this term may therefore cause some uneasiness among the investigators accustomed to the characteristics often associated with this terminology in classical theories of plasticity. Of course, metallurgists liberally use plastic deformation for creep strain in metals. We will return to this topic in Section 1.7.

      

      Trinity of Strain

      ELASTIC

      DELAYED ELASTIC

      VISCOUS

      It is recognized that inelastic or permanent viscous