Three-dimensional characterization of microstructurally small fatigue-crack evolution using quantitative fractography combined with post-mortem X-ray tomography and high-energy X-ray diffraction microscopy

Abstract An experimental methodology based on post-mortem measurements is proposed to quantify rates of propagation and crack-surface crystallography of a 3-D, naturally nucleated, microstructurally small fatigue crack (MSFC) in a polycrystalline aluminum alloy (Al–Mg–Si). The post-mortem characterization involves: scanning electron microscopy-based fractography to measure crack-front projections (marker bands) at known cycle counts during the load history, X-ray computed tomography to provide high-resolution reconstructions of the 3-D crack-surface morphology, and near-field high-energy X-ray diffraction microscopy to provide 3-D grain geometries and orientations adjacent to fatigue-crack surfaces. Local MSFC-propagation rates are measured by accounting for the 3-D crack-surface morphology and varied by two orders of magnitude in the Al–Mg–Si specimen. Both intergranular and transgranular MSFC evolution were observed, with the latter occurring along a wide range of crystallographic planes. The findings demonstrate: (i) the complexity and variability of 3-D MSFC evolution in the Al–Mg–Si alloy; and (ii) the viability of the post-mortem characterization approach for quantifying 3-D MSFC evolution in polycrystalline alloys.

[1]  Richard P. Gangloff,et al.  Effect of corrosion severity on fatigue evolution in Al–Zn–Mg–Cu , 2010 .

[2]  W. J. Baxter,et al.  Growth of slip bands during fatigue of 6061-T6 aluminum , 1988, Metallurgical and Materials Transactions A.

[3]  A. Rollett,et al.  Observation of recovery and recrystallization in high-purity aluminum measured with forward modeling analysis of high-energy diffraction microscopy , 2012 .

[4]  W. Ludwig,et al.  Three-dimensional in situ observations of short fatigue crack growth in magnesium , 2011 .

[5]  B. N. Cox,et al.  Inductions from Monte Carlo simulations of small fatigue cracks , 1989 .

[6]  Robert S. Piascik,et al.  Environmental fatigue of an Al-Li-Cu alloy: Part II. Microscopic hydrogen cracking processes , 1993, Metallurgical and Materials Transactions A.

[7]  A. Wilkinson,et al.  Experimental and computational studies of low cycle fatigue crack nucleation in a polycrystal , 2007 .

[8]  A. Wilkinson,et al.  Influence of grain orientations on the initiation of fatigue damage in an Al–Li alloy , 1999, Journal of microscopy.

[9]  W. Ludwig,et al.  3D characterisation of the nucleation of a short fatigue crack at a pore in a cast Al alloy using high resolution synchrotron microtomography , 2005 .

[10]  Robert M. Suter,et al.  Adaptive reconstruction method for three-dimensional orientation imaging , 2013 .

[11]  U. Krupp,et al.  Microstructurally short fatigue crack initiation and growth in Ti-6.8Mo-4.5Fe-1.5Al , 2000 .

[12]  James M. Larsen,et al.  Effect of initiation feature on microstructure-scale fatigue crack propagation in Al–Zn–Mg–Cu , 2012 .

[13]  Robert M. Suter,et al.  Forward modeling method for microstructure reconstruction using x-ray diffraction microscopy: Single-crystal verification , 2006 .

[14]  Richard P. Gangloff,et al.  Environmental Fatigue-Crack Surface Crystallography for Al-Zn-Cu-Mg-Mn/Zr , 2008 .

[15]  P. Wynblatt,et al.  Correlation Between Grain‐Boundary Segregation and Grain‐Boundary Plane Orientation in Nb‐Doped TiO2 , 2005 .

[16]  J. E. Hilliard,et al.  Quantitative analysis of scanning electron micrographs , 1972 .

[17]  M. Preuss,et al.  Fatigue and Damage in Structural Materials Studied by X-Ray Tomography , 2012 .

[18]  Morris E. Fine,et al.  Fatigue Crack initiation and microcrack growth in 2024-T4 and 2124-T4 aluminum alloys , 1979 .

[19]  Richard P. Gangloff,et al.  Fatigue crack formation and growth from localized corrosion in Al–Zn–Mg–Cu , 2009 .

[20]  S. Agnew,et al.  Fatigue crack surface crystallography near crack initiating particle clusters in precipitation hardened legacy and modern Al–Zn–Mg–Cu alloys , 2011 .

[21]  W. Ludwig,et al.  Observations of Intergranular Stress Corrosion Cracking in a Grain-Mapped Polycrystal , 2008, Science.

[22]  S. Agnew,et al.  Uncertainty in the determination of fatigue crack facet crystallography , 2005 .

[23]  A. Ingraffea,et al.  Effect of chemical milling on low-cycle fatigue behavior of an Al–Mg–Si alloy , 2013 .

[24]  J. Knott,et al.  Crystallographic fatigue crack growth in aluminium alloys , 1975 .

[25]  R. Gangloff,et al.  Determining fracture facet crystallography using electron backscatter patterns and quantitative tilt fractography , 1993 .

[26]  Henry Proudhon,et al.  Three-dimensional characterisation and modelling of small fatigue corner cracks in high strength Al-alloys , 2012 .

[27]  D. McDowell,et al.  Microstructure-sensitive computational modeling of fatigue crack formation , 2010 .

[28]  M. Preuss,et al.  3-D observations of short fatigue crack interaction with la2mellar and duplex microstructures in a two-phase titanium alloy , 2011 .

[29]  Peter Cloetens,et al.  Study of the interaction of a short fatigue crack with grain boundaries in a cast Al alloy using X-ray microtomography , 2003 .

[30]  Lorrie Molent,et al.  Marker loads for quantitative fractography of fatigue cracks in aerospace alloys , 2009 .

[31]  B. N. Cox,et al.  Monte Carlo simulations of the growth of small fatigue cracks , 1988 .

[32]  A. Rollett,et al.  Polycrystal Plasticity: Comparison Between Grain- Scale Observations of Deformation and Simulations , 2014 .

[33]  Richard P. Gangloff,et al.  Crystallography of Fatigue Crack Propagation in Precipitation-Hardened Al-Cu-Mg/Li , 2007 .

[34]  J. Buffière,et al.  Three-dimensional study of a fretting crack using synchrotron X-ray micro-tomography , 2007 .

[35]  S. Agnew,et al.  Diffraction characterization of microstructure scale fatigue crack growth in a modern Al–Zn–Mg–Cu alloy , 2012 .

[36]  K. Chan,et al.  Roles of microstructure in fatigue crack initiation , 2010 .

[37]  Henning Friis Poulsen,et al.  Three-Dimensional X-Ray Diffraction Microscopy: Mapping Polycrystals and their Dynamics , 2004 .

[38]  H. Noguchi,et al.  Study on dominant mechanism of high-cycle fatigue life in 6061-T6 aluminum alloy through microanalyses of microstructurally small cracks , 2012 .

[39]  P. Forsyth Fatigue damage and crack growth in aluminium alloys , 1963 .

[40]  James M. Larsen,et al.  Driving forces for localized corrosion‐to‐fatigue crack transition in Al–Zn–Mg–Cu , 2011 .

[41]  V. Randle,et al.  Combined application of electron backscatter diffraction and stereo‐photogrammetry in fractography studies , 2001, Journal of microscopy.

[42]  Philip J. Withers,et al.  High Resolution X-ray Tomography of Short Fatigue Crack Nucleation in Austempered Ductile Cast Iron , 2004 .

[43]  L. Edwards,et al.  On the blocking effect of grain boundaries on small crystallographic fatigue crack growth , 1994 .

[44]  Michael Herbig,et al.  3-D growth of a short fatigue crack within a polycrystalline microstructure studied using combined diffraction and phase-contrast X-ray tomography , 2011 .

[45]  J. Papazian,et al.  Observations of fatigue crack initiation in 7075-T651 , 2010 .

[46]  P. Cloetens,et al.  New opportunities for 3D materials science of polycrystalline materials at the micrometre lengthscale by combined use of X-ray diffraction and X-ray imaging , 2009 .

[47]  A. Rollett,et al.  Three-dimensional plastic response in polycrystalline copper via near-field high-energy X-ray diffraction microscopy , 2012 .

[48]  R. Ritchie,et al.  Propagation of short fatigue cracks , 1984 .

[49]  William L. Ross,et al.  Composite Overwrapped Pressure Vessels: Database Extension Task 3.0 and Impact Damage Effects Control Task 8.0 , 2002 .

[50]  M. J. Bos,et al.  ICAF 2009, Bridging the Gap between Theory and Operational Practice , 2009 .