Chapter 4  Metal Alloys: Their Structure and Strengthening by Heat Treatment

                                    grain growth (Section 1.7) are examples of thermal treatment, involving changes in
                                    the grain structure of the alloy.
                                        This section focuses on the microstructural changes in the iron-carbon system.
                                    Because of their technological significance, the structures considered are pearlite,
                                    spheroidite, bainite, martensite, and tempered martensite. The heat-treatment
                                    processes described are annealing, quenching, and tempering.

                                    Pearlite.  If the ferrite and cementite lamellae in the pearlite structure of the eutec-
                                    toid steel shown in Fig. 4.1 1 are thin and closely packed, the microstructure is called
                                    fine pearlite; if they are thick and widely spaced, it is called coarse pearlite. The
                                    difference between the two depends on the rate of cooling through the eutectoid
                                   temperature, which is the site of a reaction in which austenite is transformed
                                    into pearlite. If the rate of cooling is relatively high (as it is in air), fine pearlite is
                                   produced; if cooling is slow (as it is in a furnace), coarse pearlite is produced.

                                    Spheroidite.  When pearlite is heated to just below the eutectoid temperature and
                                   then held at that temperature for a period of time (subcritical annealing, Section 4.1 1),
                                    such as for a day at 700°C, the cementite lamellae transform to roughly spherical
                                    shapes (Fig. 4.14). Unlike the lamellar shapes of cementite, which act as stress rais-
                                   ers, spheroidites (spherical particles) are less conducive to stress concentration be-
                                   cause of their rounded shapes. Consequently, this structure has higher toughness
                                    and lower hardness than the pearlite structure. In this form, it can be cold worked,
                                    because the ductile ferrite has high toughness and the spheroidal carbide particles
                                   prevent the initiation of cracks within the material.

                                    Bainite.  Visible only through electron microscopy, bainite is a very fine microstruc-
                                   ture consisting of ferrite and cementite, similar to pearlite, but having a different
                                   morphology. Bainite can be produced in steels with alloying elements and at cooling
                                   rates that are higher than those required for transformation to pearlite. This struc-
                                   ture, called bainitic steel (after E.C. Bain, 1891-1971 ), is generally stronger and more
                                   ductile than pearlitic steels at the same hardness level.

                                    Martensite. When austenite is cooled at a high rate, such as by quenching it in
                                   water, its fcc structure is transformed into a body-centered tetragonal (bct) struc-
                                   ture. This structure can be described as a body-centered rectangular prism that is
          »:,@~;f-»2s»=;»»ss~5~f         -= 5  Because martensite does not have as many slip systems as a bcc struc-
                                              slightly elongated along one of its principal axes (see Fig. 4.9d). This
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                                                            is called martensite (after A. Martens, 1850-1914).
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                                              austenite transforms to martensite, its volume increases (and hence its
          >-.. .55 Q; ,leaf    ~ ®@f»€3ii_““’D¢   ”  in densities that result from phase transformations. For example, when
                                              density decreases) by as much as 4%. A similar, but smaller, volume
                                              expansion also occurs when austenite transforms to pearlite. These
                                              expansions, and the thermal gradients present in a quenched part, cause
          FIGURE 4.l4 Microstructure of eutectoid
          steel. Spheroidite is formed by tempering  internal stresses within the body. They may cause parts to undergo
                                              distortion or even to crack during heat treatment; quench cracking of
          the steel at 700°C. Magnification: 1000><.
                                              steels is caused by rapid cooling during quenching.