This study investigates the effects of cementite particle size and coarsening on ferrite grain growth kinetics in low carbon steel through annealing at 650 °C and analytical modeling. Two thermomechanically processed sample sets exhibited similar initial ferrite grain sizes but different cementite sizes, with smaller particles leading to a grain growth rate increase of up to 58% and a characteristic two-stage growth. Modeling indicates that precipitate pinning and solute drag influence grain growth; however, the dominant factor is the variation in the grain growth proportionality constant, strongly governed by the cementite coarsening rate. This work advances understanding by quantitatively linking cementite microstructural evolution to ferrite grain growth, addressing a gap in analytical modeling of this process.
NajafkhaniFMirzadehHZamaniM. Effect of intercritical annealing conditions on grain growth kinetics of dual phase steel. Met Mater Int2019; 25: 1039–1046.
2.
FanDChenSChenL-Q. Computer simulation of grain growth kinetics with solute drag. J Mater Res1999; 14: 1113–1123.
3.
YeLMeiBYuL. The modeling and simulation of austenite grain growth in 25Cr2Ni4MoV nuclear-power rotor steel. Metals (Basel)2023; 13: 1072.
4.
LimingFAidangSWeiW. Effect of nb solute drag and nbc precipi-tate pinning on the recrystallization grain growth in low carbon nb–microacloyed steel. Acta Metall SINica2010; 46: 832–837.
5.
MaityJ. An analytical model of grain growth considering the conjoint effects of precipitate pinning and solute drag in steel. Philos Mag Lett2022; 102: 307–323.
6.
ZhouTZurobHSO’MalleyRJ. A New Alloy System Having Autogenous Grain Pinning at High Temperature, In: Materials Processing Fundamentals 2019, 2019, pp.73-86. Springer.
7.
ShahandehSMilitzerM. Grain boundary curvature and grain growth kinetics with particle pinning. Philos Mag2013; 93: 3231–3247.
8.
GallegoJRodriguesARAssisCLFd,et al.Second phase precipitation in ultrafine-grained ferrite steel. Mater Res2014; 17: 527–534.
9.
OikawaTEnomotoM. Distribution of carbide particles and its influence on grain growth of ferrite in Fe-C alloys containing B and V, In: Proceedings of the 1 st international conference on 3d materials science, 2016, pp.107-112. Springer.
10.
OikawaTZhangJJEnomotoM,et al.Influence of carbide particles on the grain growth of ferrite in an fe–0.1 C–0.09 V alloy. ISIJ Int2013; 53: 1245–1252.
11.
ZhaoM-CHanamuraTQiuH,et al.Microstructural evolution of submicron sized ferrite in bimodal structural ultrafine grained ferrite/cementite steels by annealing below austenized temperature. Metallurgical and Materials Transactions A2006; 37: 1657–1664.
12.
ChangKKwonJRheeC-K. Role of second-phase particle morphology on 3D grain growth: a phase-field approach. Comput Mater Sci2016; 124: 438–443.
13.
ChangK. Current trend of second phase particle-grain boundary interaction research using computer simulations. Journal of Powder Materials2020; 27: 339–342.
14.
BlaouiMMAzizaBAbderazekH,et al.Study of the grain growth kinetics and its influence on mechanical behavior of plain carbon steel. SAE International Journal of Materials and Manufacturing2023; 16: 15–24.
15.
NajafkhaniFKheiriSPourbahariB,et al.Recent advances in the kinetics of normal/abnormal grain growth: a review. Archives of Civil and Mechanical Engineering2021; 21: 1–20.
16.
M.-h. Park, A. Shibata, N. Tsuji. Challenging ultra grain refinement of ferrite in low-C steel only by heat treatment. Frontiers in Materials2020; 7: 604792.
17.
FangHMecozziMBrückE, et al.Analysis of the grain size evolution for ferrite formation in fe-C-mn steels using a 3D model under a mixed-mode interface condition. Metallurgical and Materials Transactions A2018; 49: 41–53.
18.
SunFKitaAOgawaT, et al.Two-and three-dimensional modeling and simulations of grain growth behavior in dual-phase steel using monte carlo and machine learning. Materials (Basel)2023; 16: 7536.
19.
ChatroudiSFCicoriaRZurobHS. Computationally efficient algorithm for modeling grain growth using hillert’s mean-field approach. Materials (Basel)2024; 17: 2341.
20.
LiuZWangCChengJ,et al.An improved grain growth model and its application in gradient heat treatment of aero-engine turbine discs. Materials (Basel)2023; 16: 6584.
21.
KraussG. Tempering of lath martensite in low and Medium carbon steels: assessment and challenges. Steel Res Int2017; 88: 1700038.
22.
ChristianJW. The Theory of Transformations in Metals and Alloys: An Advanced Textbook in Physical Metallurgy. Germany: Oxford, 1965.
23.
SongEJBhadeshiaHSuhD-W. Effect of hydrogen on the surface energy of ferrite and austenite. Corros Sci2013; 77: 379–384.
24.
GamsjägerEFischerFDSvobodaJ. Influence of non-metallic inclusions on the austenite-to-ferrite phase transformation. Mater Sci Eng A2004; 365: 291–297.
25.
DebPChaturvediM. Coarsening behavior of cementite particles in a ferrite matrix in 10B30 steel. Metallography1982; 15: 341–354.
26.
DevraVKMaityJ. Solute drag effect on austenite grain growth in hypoeutectoid steel. Philos Mag Lett2020; 100: 245–259.
27.
BaldanA. Review progress in ostwald ripening theories and their applications to nickel-base superalloys part I: ostwald ripening theories. J Mater Sci2002; 37: 2171–2202.
28.
EnomotoMHayashiK. Simulation of cementite coarsening and ferrite grain growth during annealing in a cold-rolled plain Medium carbon steel. Metallurgical and Materials Transactions A2025; 56: 2277–2292.
29.
ZhaoM-CHanamuraTQiuH, et al.Grain growth and Hall–petch relation in dual-sized ferrite/cementite steel with nano-sized cementite particles in a heterogeneous and dense distribution. Scr Mater2006; 54: 1193–1197.
