Microstructural effects on the stability of retained austenite in transformation induced plasticity steels

Mark, Alison Fiona Lockie

03 January 2008

Transformation Induced Plasticity (TRIP) steels have both high strength and high ductility. Retained austenite in the microstructure, upon straining, transforms to martensite and this absorbs energy and improves the work hardening of the steel, giving improved elongation. The transformation can be either stress-assisted or strain-induced and the initiation and the mechanism depend on the composition of, the size and shape of, and the phases surrounding, the austenite grains. It is important to understand the relationship between these variables and the properties of the TRIP steel. The aim of this work was to determine how the microstructure of the TRIP steel affects the transformation. Four experimental microstructures were developed, containing austenite grains with different sizes, shapes, and surrounding phases. The Fine microstructure had thin elongated austenite laths between fine bainitic ferrite laths, the Coarse microstructure had elongated austenite grains between coarser bainitic ferrite laths, the Equiaxed microstructure had equiaxed austenite grains in a matrix of equiaxed ferrite and the Acicular microstructure had elongated austenite grains surrounded by recovered ferrite laths. Tensile tests were performed and detailed characterization, using neutron diffraction, was done of samples with the four microstructures. The variation in the amount of austenite during deformation was measured. The tensile tests revealed that the microstructures had different mechanical properties and different transformation behaviours. Fine had the lowest elongation and the highest strength. Acicular and Equiaxed had good elongation but lower strength. Coarse had intermediate strength and Equiaxed had sustained work hardening. The transformation in Fine and Coarse was minimal. Coarse had some slow, steady transformation, but Fine may have had none. The transformation in Equiaxed was larger. It started quickly and then slowed at higher strains. The austenite in Acicular transformed steadily. The predominant mechanism of transformation was stress-assisted transformation, with strain-induced transformation occurring only in Equiaxed. The results of this work showed that the influence of the surrounding phases on the stability of the austenite is significant. The differences in the transformation behaviour of the four microstructures seemed to be due more to the surrounding phases than the grain size or the composition, although both these factors also played a role. / Thesis (Ph.D, Mechanical and Materials Engineering) -- Queen's University, 2007-12-14 13:35:07.248

TRIP steel

Steel microstructure

Martensite transformation

Atomistic Study of Motion of Twin Boundaries: Nucleation, Initiation of Motion, and Steady Kinetics

Lu, Chang-Tsan

01 December 2013

The materials that exhibit martensite transformation have very important applications in engineering, and the microstructures of the materials play a key role foraffecting their mechanical behavior in macroscope. Therefore many attentions havebeen drawn for studying the related problems. This work focuses on the motion oftwin boundaries. Three questions are being asked: how is a twin boundary is nucleated in a homogenous (untwinned) material? After the twin boundary is nucleated,how is its motion initiated? How fast does it move? This study provides an atomisticunderstanding for these three questions. Linear stability analysis is firstly applied to capture the initiation of motion of atwin boundary. When a twin boundary is about to move, the lowest eigenvalue of thesystem Hessian drops to zero. And the corresponding eigenvector predicts accuratelythe way in which the twin boundary is going to move. The same idea is applied toinvestigate how motion of an irrational twin boundary is initiated. Atomic modelsof irrational twin boundaries are constructed by employment of continuum models,provided that the point group of rotations which relate two variants is extended toany rotations in plane. The zero eigenvectors reveal the complicated behavior ofmotion of irrational twin boundaries. The problem of nonuniqueness of kinetic relations proposed by Schwetlick andZimmer is solved in a thermoelasticity framework. By calculating the net heat fluxcrossing the phase boundary which is carried by the phonons, a unique kinetic relationcan be determined. Finally, a nonlocal criterion for nucleation of twin boundariesis proposed. By checking the stiffness of each unit cell evaluated with respect to asingle variable that represents the displacement along the unit cell diagonal direction,locations and the orientations of nucleated twin boundaries can be predicted.

Linear Stability Analysis

Molecular Statics

Molecular dynamics

Kinetic Relations

Nucleation

Martensite Transformation

Twin Boundary

Civil and Environmental Engineering

Extended TOF-SIMS analysis on low-nickel austenitic stainless steels: The influence of oxide layers on hydrogen embrittlement

Izawa, Chika

21 July 2015

No description available.

530

Physik (PPN621336750)

Oxide layer

Hydrogen Embrittlement

Austenitic Stainless Steel

TOF-SIMS

SIMS

Md30

Surface Analysis

Martensite Transformation

An Investigation of the Structural and Magnetic Transitions in Ni-Fe-Ga Ferromagnetic Shape Memory Alloys

Heil, Todd M.

06 January 2006

The martensite and magnetic transformations in Ni-Fe-Ga ferromagnetic shape memory alloys are very sensitive to both alloy chemistry and thermal history. A series of Ni-Fe-Ga alloys near the prototype Heusler composition (X2YZ) were fabricated and homogenized at 1423 °K, and a Ni₅₃Fe₁₉Ga₂₈ alloy was subsequently annealed at various temperatures below and above the B2/L21 ordering temperature. Calorimetry and magnetometry were employed to measure the martensite transformation temperatures and Curie temperatures. Compositional variations of only a few atomic percent result in martensite start temperatures and Curie temperatures that differ by about 230 °K degrees and 35 °K degrees, respectively. Various one-hour anneals of the Ni₅₃Fe₁₉Ga₂₈ alloy shift the martensite start temperature and the Curie temperature by almost 70 °K degrees. Transmission electron microscopy investigations were conducted on the annealed Ni₅₃Fe₁₉Ga₂₈ alloy. The considerable variations in the martensite and magnetic transformations in these alloys are discussed in terms of microstructural differences resulting from alloy chemistry and heat treatments. The phase-field method has been successfully employed during the past ten years to simulate a wide variety of microstructural evolution in materials. Phase-field computational models describe the microstructure of a material by using a set of field variables whose evolution is governed by thermodynamic functionals and kinetic continuum equations. A two dimensional phase-field model that demonstrates the ferromagnetic shape memory effect in Ni2MnGa is presented. Free energy functionals are based on the phase-field microelasticity and micromagnetic theories; they account for energy contributions from martensite variant boundaries, elastic strain, applied stress, magnetocrystalline anisotropy, magnetic domain walls, magnetostatic potential, and applied magnetic fields. The time-dependent Ginzburg-Landau and Landau-Lifshitz kinetic continuum equations are employed to track the microstructural and magnetic responses in ferromagnetic shape memory alloys to applied stress and magnetic fields. The model results show expected microstructural responses to these applied fields and could be potentially utilized to generate quantitative predictions of the ferromagnetic shape memory effect in these alloys. / Ph. D.

Martensite Transformation

Ni-Fe-Ga

Ferromagnetic Shape Memory Alloys

Ferromagnetic Shape Memory Effect

Phase-Field Computational Model

Estudo comparativo da deformação a frio e da resistência à corrosão nos aços inoxidáveis austeníticos AISI 201 e AISI 304. / Comparative study of the cold deformation and corrosion resistance of AISI 201 and AISI 304 austenitic stainless steels.

Morais, Viviane Lima de

24 June 2010

A crescente demanda de aplicações de aços inoxidáveis austeníticos e a constante pressão para redução de custo nas empresas siderúrgicas, devido à alta volatilidade no custo do níquel, resultaram em novos desenvolvimentos de aços da série 200. Esta nova classe de aços inoxidáveis austeníticos contém elevados teores de manganês e nitrogênio em substituição ao elemento níquel. A justificativa para a realização deste trabalho é a escassez de estudos comparativos entre aços inoxidáveis austeníticos da série 200 e série 300 disponíveis na literatura em relação ao comportamento da transformação de fase induzida pela deformação e da resistência à corrosão. Os principais fatores que afetam a microestrutura no endurecimento por deformação são: a energia de defeito de empilhamento, composição química, temperatura, grau, taxa e modo de deformação. Realizou-se uma análise crítica e adequação dos conceitos de níquel e cromo equivalente para os aços AISI 201 e AISI 304. Amostras desses aços foram solubilizadas, laminadas e racionadas em diferentes condições para caracterização microestrutural com o auxílio de técnicas de microscopia óptica, microscopia eletrônica de varredura, difração de raios X, ferritoscópio e microdureza. Curvas de endurecimento em função do grau de deformação, fração volumétrica de martensita em função do grau de deformação, assim como a evolução microestrutural e sua respectiva identificação de fase com o grau de deformação foram resultados obtidos deste trabalho. Em geral, aumentando a deformação plástica a frio, maior é a dureza para ambos os aços e maior é a fração volumétrica de martensita induzida por deformação. O aço AISI 201 é mais susceptível a transformação de fase do que o aço AISI 304 devido a sua menor EDE. Ensaios eletroquímicos de espectroscopia de impedância eletroquímica e polarização potenciodinâmica anódica foram realizados para avaliação da resistência a corrosão e para avaliar o comportamento da repassivação. Ambos os aços apresentaram comportamento similares quanto à resistência à corrosão, além de apresentarem potenciais de corrosão da ordem de 10-8 A/cm², típico de materiais passivos. / The continuous increase in the application demand of austenitic stainless steels and the constant pressure for cost reduction in the steelmaking industry, due to the high instability of nickel price, has conduced to new developments of the AISI 200 series steels. This new austenitic stainless steel series employes high manganese and nitrogen contents in substitution to nickel. The reason of this work is the lack of comparative studies in the literature between austenitic stainless steels of 200 and 300 series relative to the martensite strain induced phase transformation and its corrosion resistance. The main factors that affect microstructure on strain-hardening are: stacking fault energy, chemical composition, temperature, strain and strain rate. A critical analysis of the concept related to the nickel and chrome equivalents for the AISI 201 and AISI 304 steels has been carried out. Samples of these steels were heat treated and cold rolled to different strains for subsequent microstructural evaluation using equipments such as optical microscope, scanning electron microscope, X-ray diffraction, microhardness and ferritoscope. Strain hardening versus strain, martensite volume fraction versus strain, as well as microstructure evolution and its respective phase identification with strain are some of the main results obtained in this study. In general, increasing the strain hardening, the higher will be the hardness of both stainless steels and higher is the induced martensite volume fraction. The AISI 201 steel presented higher susceptibility to induced phase transformation in comparison to the AISI 304 steel due to its lower stacking fault energy. Electrochemical impedance spectroscopy and anodic potenciodynamic polarization were the techniques used in this work to evaluate the corrosion resistance and passivation behavior respectively. Both steels presented similar corrosion resistance, apart from presenting a corrosion potential of about 10-8 A/cm² , which is typical for passivated materials.

Aços inoxidáveis austeníticos

AISI 201

AISI 201

AISI 304

AISI 304

Austenitic stainless steel

Corrosion resistance

Resistência à corrosão

Strain hardening

Strain induced martensite transformation

Estudo comparativo da deformação a frio e da resistência à corrosão nos aços inoxidáveis austeníticos AISI 201 e AISI 304. / Comparative study of the cold deformation and corrosion resistance of AISI 201 and AISI 304 austenitic stainless steels.

Viviane Lima de Morais

24 June 2010

A crescente demanda de aplicações de aços inoxidáveis austeníticos e a constante pressão para redução de custo nas empresas siderúrgicas, devido à alta volatilidade no custo do níquel, resultaram em novos desenvolvimentos de aços da série 200. Esta nova classe de aços inoxidáveis austeníticos contém elevados teores de manganês e nitrogênio em substituição ao elemento níquel. A justificativa para a realização deste trabalho é a escassez de estudos comparativos entre aços inoxidáveis austeníticos da série 200 e série 300 disponíveis na literatura em relação ao comportamento da transformação de fase induzida pela deformação e da resistência à corrosão. Os principais fatores que afetam a microestrutura no endurecimento por deformação são: a energia de defeito de empilhamento, composição química, temperatura, grau, taxa e modo de deformação. Realizou-se uma análise crítica e adequação dos conceitos de níquel e cromo equivalente para os aços AISI 201 e AISI 304. Amostras desses aços foram solubilizadas, laminadas e racionadas em diferentes condições para caracterização microestrutural com o auxílio de técnicas de microscopia óptica, microscopia eletrônica de varredura, difração de raios X, ferritoscópio e microdureza. Curvas de endurecimento em função do grau de deformação, fração volumétrica de martensita em função do grau de deformação, assim como a evolução microestrutural e sua respectiva identificação de fase com o grau de deformação foram resultados obtidos deste trabalho. Em geral, aumentando a deformação plástica a frio, maior é a dureza para ambos os aços e maior é a fração volumétrica de martensita induzida por deformação. O aço AISI 201 é mais susceptível a transformação de fase do que o aço AISI 304 devido a sua menor EDE. Ensaios eletroquímicos de espectroscopia de impedância eletroquímica e polarização potenciodinâmica anódica foram realizados para avaliação da resistência a corrosão e para avaliar o comportamento da repassivação. Ambos os aços apresentaram comportamento similares quanto à resistência à corrosão, além de apresentarem potenciais de corrosão da ordem de 10-8 A/cm², típico de materiais passivos. / The continuous increase in the application demand of austenitic stainless steels and the constant pressure for cost reduction in the steelmaking industry, due to the high instability of nickel price, has conduced to new developments of the AISI 200 series steels. This new austenitic stainless steel series employes high manganese and nitrogen contents in substitution to nickel. The reason of this work is the lack of comparative studies in the literature between austenitic stainless steels of 200 and 300 series relative to the martensite strain induced phase transformation and its corrosion resistance. The main factors that affect microstructure on strain-hardening are: stacking fault energy, chemical composition, temperature, strain and strain rate. A critical analysis of the concept related to the nickel and chrome equivalents for the AISI 201 and AISI 304 steels has been carried out. Samples of these steels were heat treated and cold rolled to different strains for subsequent microstructural evaluation using equipments such as optical microscope, scanning electron microscope, X-ray diffraction, microhardness and ferritoscope. Strain hardening versus strain, martensite volume fraction versus strain, as well as microstructure evolution and its respective phase identification with strain are some of the main results obtained in this study. In general, increasing the strain hardening, the higher will be the hardness of both stainless steels and higher is the induced martensite volume fraction. The AISI 201 steel presented higher susceptibility to induced phase transformation in comparison to the AISI 304 steel due to its lower stacking fault energy. Electrochemical impedance spectroscopy and anodic potenciodynamic polarization were the techniques used in this work to evaluate the corrosion resistance and passivation behavior respectively. Both steels presented similar corrosion resistance, apart from presenting a corrosion potential of about 10-8 A/cm² , which is typical for passivated materials.

Aços inoxidáveis austeníticos

AISI 201

AISI 304

Resistência à corrosão

AISI 201

AISI 304

Austenitic stainless steel

Corrosion resistance

Strain hardening

Strain induced martensite transformation