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Materials Science and Technology Volume 29, 2013 - Issue 4
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Review

The Bainite Controversy

L C D Fielding Department of Materials Science and MetallurgyUniversity of Cambridge, UKCorrespondence[email protected]
Pages 383-399 | Received 10 Oct 2012, Accepted 02 Nov 2012, Published online: 12 Nov 2013

References

  • Aaronson HI: in ‘The mechanism of phase transformations in crystalline solids’, Monograph and Report Series No. 33, 207–281; 1969, London, Institute of Metals.
  • Hehemann RF, Kinsman KR, Aaronson HI: ‘A debate on the bainite reaction’, Metall. Mater. Trans. B, 1972, 3B, 1077–1094.
  • Aaronson HI, Spanos G, Reynolds WT: ‘A progress report on the definitions of bainite’, Scr. Mater., 2002, 47, 139–144.
  • Aaronson HI: ‘Reply to a discussion by J.W. Christian and D.V. Edmonds of papers by Aaronson and co-workers on the proeutectoid ferrite and bainite reactions’, Scr. Metall., 1988, 22, (4), 567–572.
  • Boswell PG, Kinsman KR, Shiflet GJ, Aaronson HI: in ‘Mechanical properties and phase transformation in engineering materials’, 445; 1986, Warrendale, PA, TMS.
  • Habraken LJ, Economopolous M: ‘Bainitic microstructures in low-carbon alloy steels and their mechanical properties’, in ‘Transformation and hardenability in steels’, 69–108; 1967, Ann Arbor, MI, Climax Molybdenum.
  • Vilella JR: Trans. AIME, 1940, 140, 332.
  • Hillert M: ‘The role of interfacial energy during solid state phase transformations’, Jernkontoret. Ann., 1957, 141, 757.
  • Bhadeshia HKDH: ‘Bainite in steels’, 2nd edn; 2001, London, Institute of Materials.
  • Bramfitt BL, Speer JG: ‘A perspective on the morphology of bainite’, Metall. Mater. Trans. A, 1990, 21A, 817–829.
  • Leont’ev BA, Kovalevskaya GV: ‘Mechanism of the bainitic transformation of austenite’, Fiz. Met. Metalloyed., 1974, 38, 1050.
  • Honeycombe RWK, Bhadeshia HKDH: ‘Steels: microstructure and properties’, 2nd edn; 1995, London, Edward Arnold.
  • Yang ZG, Fang HS: ‘An overview on bainite formation in steels’, Curr. Opin. Solid St. M., 2005, 9, (6), 277–286.
  • Samuels LE: ‘Light microscopy of carbon steels’; 1999, Materials Park, OH, ASM International.
  • Davenport ES, Bain EC: ‘Transformation of austenite at constant subcritical temperatures’, Trans. Am. Inst. Min. Metall. Eng., 1930, 90, 117–154.
  • Robertson JM: ‘The microstructure of rapidly cooled steel’, J. Iron. Steel Inst., 1929, 119, 391–424.
  • Mehl RF: ‘Mechanism and rate of decomposition from austenite’, in ‘Hardenability of alloy steels’, 1–65; 1939, ASM.
  • Chang LC, Bhadeshia HKDH: ‘Microstructure of lower bainite formed at large undercoolings below bainite start temperature’, Mater. Sci. Technol., 1996, 12, 233–236.
  • Hehemann RF: ‘The bainite transformation’, in ‘Phase transformations’, (ed. , Aaronson H I, Zackay V F), 397–432; 1970 ASM.
  • Troiano AR: Trans. ASM, 1949, 41, 1093–1112.
  • Klier EP, Lyman T: ‘The bainite reaction in hypoeutectoid steels’, Trans. AIMME. Met. Technol., 1944, 395–422.
  • Lyman T, Troiano AR: ‘Influence of carbon content upon the transformations in 3% chromium steel’, Trans. ASM, 1946, 37, 402–448.
  • Hultgren J: J. Iron. Steel Inst., 1926, 114, 421–422.
  • Hillert M: ‘The growth of ferrite, bainite and martensite’, Internal report, Swedish Institute for Metals Research, Stockholm, Sweden, 1960.
  • Borgenstam A, Hillert M, Agren J: ‘Metallographic evidence of carbon diffusion in the growth of bainite’, Acta Mater., 2009, 57, 3242–3252.
  • Wever F, Jellinghaus W: ‘Transformation kinetics of austenite II. dilatometry investigations of austenite decomposition’, Mitt. Kaiser-Wilhelm-Inst. Eisenforch, 1932, 14, 85.
  • Portevin A, Chevenard P: ‘The transformations during the cooling of steels’, P. Compt. Rend, 1937, 204, 772.
  • Zener C: ‘Kinetics of the decomposition of austenite’, Trans. Am. Inst. Min. Metall. Eng., 1946, 167, 550–595.
  • Vilella JR, Guellich GE, Bain EC: ‘On naming the aggregate constituents in steel’, Trans. ASM, 1936, 24, 225–261.
  • Bain EC: ‘Functions of the alloying elements in steel’; 1939, Cleveland, OH, American Society for Metals.
  • Hultrgen A: ‘Isothermal transformation of austenite’, Trans. ASM, 1947, 39, 915–989.
  • Hillert M: ‘Paraequilibrium’, Technical report, Swedish Institute for Metals Research, Stockholm, Sweden, 1953.
  • Bowman P: ‘The partition of molybdenum in steel and its relation to hardenability’, Am. Soc. Metals, 1945, 35, 112.
  • Davenport ES: ‘Isothermal transformation in steels’, Trans. ASM, 1939, 27, 837–886.
  • Murakami T, Imai Y: ‘An investigation on isothermal transformation in steels. 1: The cause of modification of s-curves of some alloy steels’, Sci. Rep. RITU, 1949, 1,2, 87–92.
  • Wever F, Lange H: ‘The transformation kinetics of austenite I. magnetic investigations of the decomposition of austenite’, Mitt. Kaiser-Wilhelm-Inst. Eisenforch, 1932, 14, 71–83.
  • Troiano AR: in discussion with C. Zener, Trans. Am. Inst. Min. Metall. Eng., 1946, 167, 550–595.
  • Zener C: ‘Equilibrium relations in medium-alloy steels’, Trans. AIME, 1946, 167, 513–534.
  • Troiano AR: in discussion with A. Hultgren, Trans. ASM, 1947, 39, 915–989.
  • Smith GV, Mehl RF: ‘Lattice relationships in decompositon of austenite to pearlite, bainite and martensite’, Trans. AIME, 1942, 150, 210–226.
  • Hull FC, Mehl RF: ‘The structure of pearlite’, Trans. ASM, 1942, 30, 381–424.
  • Dubé A, Alexander BH: in discussion with A. Hultgren, Trans. ASM, 1947, 39, 915–989.
  • Ko T, Cottrell SA: ‘The formation of bainite’, J. Iron. Steel Inst., 1952, 172, 307–313.
  • Speich GR, Cohen M: ‘The growth rate of bainite’, Trans. Metall. Soc. AIME, 1960, 218, 1050–1059.
  • Goodenow RH, Matas SJ, Hehemann RF: ‘Growth kinetics and the mechanism of the bainite transformation’, Trans. Met. Soc. AIME, 1963, 227, 651–658.
  • Kaufman L, Radcliffe SV, Cohen M: ‘Thermodynamics of the bainite reaction’, (ed. , Zackay V F, Aaronson H I, ed), in ‘The decomposition of austenite by diffusional processes’, 313–352; 1962, New York, Interscience.
  • Trivedi R: ‘Role of interfacial free energy and interface kinetics during the bainite reaction’, Metall. Trans., 1970, 1, 921–927.
  • Townsend RD, Kirkaldy JS: Trans. ASM, 1968, 61, 605.
  • Simonen EP, Aaronson HI, Trivedi R: ‘Lengthening kinetics of ferrite and bainite sideplate’, Metall. Trans., 1973, 4, 1239.
  • Miodownik AP: ‘The mechanism of phase transformations in metals’, Inst. Met. Monograph Rep., 1956, 18, 319.
  • Oblak JM, Hehemann RF: ‘Structure and growth of widmanstatten ferrite and bainite’, in ‘Transformations and hardenability in steels’, 15–30; 1967, Ann Arbor, MI, Climax Molybdenum.
  • Matas SJ, Hehemann RF: ‘The structure of bainite in hypoeutectoid steels’, TMS-AIME, 1961, 221, 179–185.
  • Deliry J: ‘Noveau carbure de fer transformation bainitique dans les aciers au carbone silicium’, Memoires Sci. Rev. Metall., 1965, 62, 527–550.
  • Irvine KJ, Pickering FB: ‘High carbon bainitic steels’, in ‘Physical properties of martensite and bainite’, Special Report 93, 110–125; 1965, London, Iron and Steel Institute.
  • Shackleton DN, Kelly PM: ‘Morphology of bainite’, in ‘Physical properties of martensite and bainite’, Special Report 93, 126–134; 1965, London, Iron and Steel Institute.
  • Christian JW: ‘The origins of surface relief effects in phase transformations’, in ‘Decomposition of austenite by diffusional processes’, (ed. , Zackay V F, Aaronson H I), 371–386; 1962, AIME, Interscience.
  • Bowles JS, Mackenzie JK: ‘The crystallography of martensite transformations, part I’, Acta Metall., 1954, 2, 129–138.
  • Shackleton DN, Kelly PM: ‘The crystallography of cementite precipitation in the bainite transformation’, Acta Metall., 1967, 15, 979–992.
  • Srinivasan GR, Wayman CM: ‘The crystallography of the bainite transformation’, Acta Metall., 1968, 16, 621–636.
  • Bain EC: ‘The nature of martensite’, Trans. AIMME, 1924, 70, 25–46.
  • Srinivasan GR, Wayman CM: ‘Transmission electron microscope studies of the bainite transformation in iron-chromium-carbon alloys’, Acta Metall., 1968, 16, (5), 609–620.
  • Kennon NF, Edwards RH: J. Aust. Inst. Metals, 1970, 15, 195.
  • Aaronson HI: ‘The proeutectoid ferrite and the proeutectiod cementite reaction’, in ‘Decompsition of austenite by diffusional processes’, (ed. , Zackay V F, Aaronson H I), 387; 1962, New York, Interscience.
  • Laird C, Aaronson HI: ‘Mechanisms of formation of θ and dissolution of θ′ precipitates in an Al-4% Cu alloy’, Acta Metall., 1966, 14, 171–185.
  • Laird C, Aaronson HI: ‘The growth of γ plates in an Al-15% Ag alloy’, Acta Metall., 1969, 17, 505–519.
  • Nemoto M:‘Growth of bainite in an iron-nickel-carbon alloy’ in ‘High voltage electron microscopy’(, Swann P R, et al..), 230–234, 1974, New York, Academic Press.
  • Watson JD, McDougall PG: ‘The crystallography of Widmanstätten ferrite’, Acta Metall., 1973, 21, (7), 961–973.
  • Aaronson HI, Hall MG, Barnett DM, Kinsman KR: ‘The Watson-McDougall shear: proof that widmanstätten ferrite cannot grow martensitically’, Scr. Metall., 1975, 9, 705–712.
  • McDougall PG: ‘Comment on “The Watson-McDougall shear: proof that Widmänstatten ferrite cannot grow martensitically”’, Scr. Metall., 1975, 9, 713–715.
  • Bhadeshia HKDH: ‘BCC-BCC orientation relationships, surface relief and displacive phase transformations in steels’, Scr. Metall., 1980, 14, 821–824.
  • Bhadeshia HKDH: ‘A rationalisation of shear transformations in steels’, Acta Metall., 1981, 29, 1117–1130.
  • Bowles JS, Wayman CM: ‘The growth mechanism of AuCu II plates’, Acta Metall., 1979, 22, 833–839.
  • Christian JW: in ‘The mechanism of phase transformations in crystalline solids’, Vol. 33, 129, 1969.
  • Bhadeshia HKDH, Edmonds DV: ‘The bainite transformation in a silicon steel’, Metall. Trans. A, 1979, 10A, 895–907.
  • Bhadeshia HKDH, Edmonds DV: ‘The mechanism of bainite formation in steels’, Acta Metall., 1980, 28, 1265–1273.
  • Le Houillier R, Begin G, Dube A: ‘A study of the peculiarities of austenite during the formation of bainite’, Metall. Trans., 1971, 2, 2645–2653.
  • Takahashi M, Bhadeshia HKDH: ‘A model for the microstructure of some advanced bainitic steels’, Mater. T. JIM, 1991, 32, 689–696.
  • Hillert M, Hoglund L, Agren J: ‘Role of carbon and alloying elements in the formation of bainitic ferrite’, Metall. Mater. Trans. A, 2004, 35A, 3693–3700.
  • Bhadeshia HKDH, Waugh AR: ‘Bainite: an atom probe study of the incomplete reaction phenomenon’, Acta Metall., 1982, 30, 775–784.
  • Bhadeshia HKDH: ‘Bainite: overall transformation kinetics’, J. Phys. Coll., C4, 1982, 43, 443–448.
  • Rees GI, Bhadeshia HKDH: ‘Bainite transformation kinetics, part I, modified model’, Mater. Sci. Technol., 1992, 8, 985–993.
  • Rees GI, Bhadeshia HKDH: ‘Bainite transformation kinetics, part II, non-uniform distribution of carbon’, Mater. Sci. Technol., 1992, 8, 994–996.
  • Singh SB, Bhadeshia HKDH: ‘Estimation of bainite plate thickness in low-alloy steels’, Mater. Sci. Eng. A, 1998, 245A, 72–79.
  • Chester N, Bhadeshia HKDH: ‘Mathematical modelling of bainite transformation kinetics’, J. Phys. IV, C5, 1997, 7, 41–46,.
  • Matsuda H, Bhadeshia HKDH: ‘Kinetics of the bainite transformation’, Proc. R. Soc. A, 2004, 460A, 1707–1722.
  • Burke JE: ‘Grain growth in alpha brass’, J. Appl. Phys., 1947, 18, 1028.
  • Lucke K, Masing G, Nolting P: Z. Metallkunde, 1956, 47, 64.
  • Bolling GF, Winegard WC: ‘Grain growth in zone-refined lead’, Acta Metall., 1958, 6, 283.
  • Aust KT, Rutter JW: Trans. Met. Soc. AIME, 1959, 215, 119.
  • Holmes EL, Winegard WC: J. Inst. Met., 1960, 88, 468.
  • Lücke K, Detert K: ‘A quantitative theory of grain-boundary motion and recrystallization in metals in the presence of impurities’, Acta Metall., 1957, 5, 628–637.
  • Bhadeshia HKDH: ‘Considerations of solute-drag in relation to transformations in steels’, J. Mater. Sci., 1983, 18, 1473–1481.
  • Kinsman KR, Aaronson HI: in ‘Transformation and hardenability in steels’, 39–53; 1967, Ann Arbor, MI, Climax Molybdenum.
  • Coates DE: ‘Diffusional growth limitations to hardenability’, Metall. Trans., 1973, 4, 2313–2325.
  • Bhadeshia HKDH: ‘Solute-drag, kinetics and the mechanism of the bainite transformation’, in ‘Phase transformation in ferrous alloys’, (ed. , Marder A R, Goldstein J I), 335–340; 1984, OH, TMS-AIME.
  • Stark I, Smith GDW, Bhadeshia HKDH: ‘The element redistribution associated with the “incomplete reaction phenomenon” in bainitic steels: an atom-probe investigation’, Proc. Int. Conf. Phase Transformations ’87, 211–215; 1988, Institute of Metals.
  • Stark I, Smith GDW, Bhadeshia HKDH: ‘The distribution of substitutional alloying elements during the bainite transformation’, Metall. Trans. A, 1990, 21A, 837–845.
  • Caballero FG, Miller MK, Babu SS, Garcia Mateo C: ‘Atomic scale observations of bainite transformation in a high carbon high silicon steel’, Acta Mater., 2007, 55, 381–390.
  • Christian JW: ‘Theory of transformations in metal and alloys, Part I’, 2nd edn; 1975, Oxford, Pergamon Press.
  • Takahashi M: ‘Recent progress: kinetics of the bainite transformation in steels’, Curr. Opin. Solid St. M., 2004, 8, 213–217.
  • Hillert M: ‘Diffusion in growth of bainite’, Metall. Mater. Trans. A, 1994, 25A, 1957–1966.
  • Ohmori Y, Maki T: ‘Bainitic transformation in view of displacive mechanism’, Mater. T. JIM, 1991, 22, 631–641.
  • Steven W, Haynes AG: ‘The temperature of formation of martensite and bainite in low-alloy steels’, J. Iron. Steel Inst., 1956, 183, 349–359.
  • Christian JW: ‘Thermodynamics and kinetics of martensite’, Proc. Int. Conf. on ‘Martensite transformations’, ICOMAT-79, 220–234; 1979, Cambridge, MA, MIT Press.
  • Oka M, Okamoto H: ‘Variation of transition temperatures from upper to lower bainites in plain carbon steels’, J. Phys. IV, 1995, C8, 503–508.
  • Takahashi M, Bhadeshia HKDH: ‘Model for transition from upper to lower bainite’, Mater. Sci. Technol., 1990, 6, 592–603.
  • Oka M, Okamoto H: ‘Isothermal transformations in hypereutectoid steels’, Proc. Int. Conf. on ‘Martensitic transformations’, ICOMAT-86, 271–275; 1986, Japan Institute of Metals.
  • Srinivasan GR, Wayman CM: ‘Isothermal transformations in an Fe-7·9 Cr-1·1 C alloy’, Trans. AIME, 1968, 242, 79–82.
  • Ohmori Y, Honeycombe RWK: ‘The isothermal transformation of plain carbon austenite’, ICSTIS Suppl. Trans. ISIJ, 1971, 11, 1160–1164.
  • Sugden AAB, Bhadeshia HKDH: ‘Lower acicular ferrite’, Metall. Trans. A, 1989, 20A, 1811–1818.
  • Reynolds WT, Li FZ, Shui CK, Aaronson HI: ‘The incomplete transformation phenomenon in Fe-C-Mo alloys’, Metall. Trans. A, 1990, 21A, 1433–1463.
  • Reynolds WT, Liu SK, Li FZ, Hartfield S, Aaronson HI: ‘An investigation of the generality of incomplete transformation to bainite in Fe-C-X alloys’, Metall. Trans. A, 1990, 21A, 1479–1491.
  • Shiflet GJ, Aaronson HI: ‘Growth and overall transformation kinetics above the bay temperature in Fe-C-Mo alloys’, Metall. Trans. A, 1990, 21A, 1413–1432.
  • Spanos G: ‘The fine structure and formation mechanism of lower bainite’, Metall. Mater. Trans. A, 1994, 25A, 1967–1980.
  • Huang DH, Thomas G: ‘Metallography of bainitic transformation in silicon containing steels’, Metall. Trans. A, 1977, 8A, 1661–1674.
  • Bhadeshia HKDH:‘Rail steels’ in ‘Future developments of metals and ceramics’(, Charles J A, et al..), 25; 1992, London, Institute of Materials.
  • Yates JK: ‘Innovation in rail steel’, Sci. Parliament, 1996, 53, 2–3.
  • Swallow E, Bhadeshia HKDH: ‘High resolution observations of displacements caused by bainitic transformation’, Mater. Sci. Technol., 1996, 12, 121–125.
  • Speich GR: ‘Decomposition of austenite by diffusional processes’, (ed. , Aaronson H I, Zackay V F), 353–369; 1962, New York, AIME, Interscience.
  • Ohmori Y: ‘The crystallography of the lower bainite transformation in a plain carbon steel’, Trans. ISIJ, 1971, 11, 95–101.
  • Sandvik BPJ: ‘The bainite reaction in Fe-Si-C alloys: the primary stage’, Metall. Trans. A, 1982, 13A, 777–787.
  • Bhadeshia HKDH: ‘The bainite transformation: unresolved issues’, Mater. Sci. Eng. A, 1999, 273A–275A, 58–66.
  • Hillert M: ‘Paradigm shift for bainite’, Scr. Mater., 2002, 47, 175–180.
  • Quidort D, Bréchet YJM: ‘Isothermal growth kinetics of bainite in 0·5% C steels’, Acta Mater., 2001, 49, 4161–4170.
  • Tszeng TC: ‘Autocatalysis in bainite transformations’, Mater. Sci. Eng. A, 2000, 293A, 185–190.
  • Fang HS, Wang JJ, Yang ZG, Li CM, Bo XZ, Zheng YK: ‘Bainite phase transformation’; 1999, Beijing, Science Press.
  • Hsu TY: ‘On bainite formation’, Metall. Mater. Trans. A, 1990, 21A, 811–816.
  • Fang H, Yang J, Yang Z, Bai B: ‘The mechanism of bainite transformation in steels’, Scr. Mater., 2002, 47, 157–162.
  • Yang Z, Zhang C, Fang H, Yang J, Bai B, Wang J: ‘A rationalisation of sympathetic nucleation-ledgewise growth theory of bainite transformation in fe-c alloys’, J. Mater. Sci. Technol., 2001, 17, 433–438.
  • Quidort D, Bréchet Y: ‘The role of carbon on the kinetics of bainite transformation in steels’, Scr. Mater., 2002, 47, 151–156.
  • Wu KM, Kagayama M, Enomoto M: ‘Kinetics of ferrite transformation in an Fe-0·28 mass% C-3 mass% Mo alloy’, Mater. Sci. Eng. A, 2003, 343A, 143–150.
  • Aaronson HI, Reynolds WT, Purdy GR: ‘Coupled-solute drag effects on ferrite formation in Fe-C-X systems’, Metall. Mater. Trans. A, 2004, 35A, 1187–1210.
  • Peet M, Babu SS, Miller MK, Bhadeshia HKDH: ‘Three-dimensional atom probe analysis of carbon distribution in low-temperature bainite’, Scr. Mater., 2004, 50, 1277–1281.
  • Humphreys ES, Fletcher HA, Hutchins JD, Garrat-Reed AJ, Reynolds WT, Aaronson HI, Purdy GR, Smith GDW: ‘Molybdenum accumulation at ferrite:austenite interfaces during isothermal transformation of an Fe-0·24% C-0·93 % Mo alloy’, Metall. Mater. Trans. A, 2004, 35A, 1223–1235.
  • Caballero FG, Bhadeshia HKDH, Mawella KJA, Jones DG, Brown P: ‘Design of novel high strength bainitic steels: Part 1’, Mater. Sci. Technol., 2001, 17, 512–516.
  • Caballero FG, Bhadeshia HKDH, Mawella KJA, Jones DG, Brown P: ‘Design of novel high strength bainitic steels: Part 2’, Mater. Sci. Technol., 2001, 17, 517–522.
  • Caballero FG, Bhadeshia HKDH, Mawella KJA, Jones DG, Brown P: ‘Very strong low temperature bainite’, Mater. Sci. Technol., 2002, 18, 279–284.
  • Garcia-Mateo C, Caballero FG, Bhadeshia HKDH: ‘Development of hard bainite’, ISIJ Int., 2003, 43, 1238–1243.
  • Garcia-Mateo C, Caballero FG, Bhadeshia HKDH: ‘Low temperature bainite’, J. Phys. IV, 2003, 112, 285–288.
  • Zhang MX, Kelly PM: ‘Determination of carbon content in bainitic ferrite and carbon distribution in austenite by using CBKLDP’, Mater. Charact., 1998, 40, 159–168.
  • Matas SJ, Hehemann RF: Trans. AIME, 1968, 221, 179.
  • Stone HJ, Peet MJ, Bhadeshia HKDH, Withers PJ, Babu SS, Specht ED: ‘Synchrotron X-ray studies of austenite and bainitic ferrite’, Proc. R. Soc. A, 2008, 464, 1009–1027.
  • Caballero FG, Miller MK, Garcia-Mateo C: ‘Carbon supersaturation of ferrite in a nanocrys-talline bainitic steel’, Acta Mater., 2010, 58, 2338–2343.
  • Caballero FG, Miller MK, Garcia-Mateo C, Cornide J: ‘New experimental evidence of the diffusionless transformation nature of bainite’, J. Alloy. Compd, 2012, to be published.
  • Bhadeshia HKDH:‘Steels for rails’ in ‘Encyclopedia of materials science: science and technology’(, Buschow K, et al..), 1–7; 2002, Pergamon Press, Elsevier Science.
  • Caballero FG, Bhadeshia HKDH: ‘Very strong bainite’, Curr. Opin. Solid St. M., 2004, 8, 251–257.
  • Garcia-Mateo C, Caballero FG, Bhadeshia HKDH: ‘Mechanical properties of low-temperature bainite’, Mater. Sci. Forum, 2005, 500–501, 495–502.
  • Bhadeshia HKDH: ‘Nanostructured bainite’, Proc. R. Soc. A, 2010, 466, 3–18.
  • Garcia-Mateo C, Caballero FG: ‘Ultra-high-strength bainitic steels’, ISIJ Int., 2005, 45, 1736–1740.
  • Garcia-Mateo C, Caballero FG, Bhadeshia HKDH: ‘Acceleration of low-temperature bainite’, ISIJ Int., 2003, 43, 1821–1825.
  • Sista V, Nash P, Sahay SS: ‘Accelerated bainitic transformation during cyclic austempering’, J. Mater. Sci., 2007, 42, 9112–9115.
  • Gomez G, Pérez T, Bhadeshia HKDH: ‘Air cooled bainitic steels for strong, seamless pipes. Part 1 - alloy design, kinetics and microstructure’, Mater. Sci. Technol., 2009, 25, 1501–1507.
  • Gomez G, Pérez T, Bhadeshia HKDH: ‘Air cooled bainitic steels for strong, seamless pipes. Part 2 - Properties and microstructure of rolled material’, Mater. Sci. Technol., 2009, 25, 1508–1512.
  • Bhadeshia HKDH: ‘Steels for bearings’, Prog. Mater. Sci., 2012, 57, 268–435.
  • Irvine KJ, Pickering FB: ‘Low-carbon bainitic steels’, J. Iron. Steel Inst., 1957, 187, 292–309.
  • Yang JR, Huang CY, Wang SC: ‘The development of ultra-low-carbon bainitic steels’, Mater. Des., 1992, 13, 355–338.
  • Zackay VF, Parker ER, Fahr D, Bush R: ‘The enhancement of ductility in high-strength steels’, Trans. Am. Soc. Metal., 1967, 60, 252–259.
  • Chatterjee S, Bhadeshia HKDH: ‘Transformation induced plasticity assisted steels: stress or strain affected martensitic transformation?’ Mater. Sci. Technol., 2007, 23, 1101–1104.
  • Frommeyer G, Brüx U, Neumann P: ‘Supra-ductile and high-strength manganese-TRIP/TWIP steels for high energy absorption purposes’, ISIJ Int., 2003, 43, 438–446.
  • Aaronson HI, Reynolds WT, Shiflet GJ, Spanos G: ‘Bainite viewed three different ways’, Metall. Trans. A, 1990, A21, 1343–1380.

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