DrJunJiang

Galindo-Nava EI, Jing YJ, Jiang J, 2018, Predicting the hardness and solute distribution during brazing of Ti-6Al-4V with TiZrCuNi filler metals, Materials Science and Engineering A: Structural Materials: Properties, Microstructure and Processing, Vol: 712, Pages: 122-126, ISSN: 0921-5093

A modelling approach for the hardness and solute distribution during brazing of Ti-6Al-4V with Ti-Zr-Cu-Ni amorphous fillers is presented. The model for hardness incorporates main strengthening mechanisms in α + β alloys and a solid–state diffusion model is employed to describe redistribution of Zr, Cu and Ni in the joints.

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Jing Y, Gao X, Su D, Zhao C, Jiang Jet al., 2018, The effects of Zr level in Ti-Zr-Cu-Ni brazing fillers for brazing Ti-6Al-4V, Journal of Manufacturing Processes, Vol: 31, Pages: 124-130, ISSN: 1526-6125

Microstructure and macro-micro mechanical properties of the joints of Ti-xZr-15Cu-10Ni brazing fillers (mass fraction x = 10, 18, 37.5) were studied by in-situ tensile test, SEM, EBSD and EDX. It was found that although the increase in the Zr level lowers the melting point of the brazing materials, which is beneficial to reduce the time of manufacturing and the wear of the equipment, the brazing joints became harder due to solid solution hardening and transformed from a ductile to brittle fracture mode. The microstructural analysis revealed that the increase of Zr level increases the grain size, which leads to high strain gradient across the brazing joints. Thus, high Zr in the brazing joints reduces the ductility of the joints. In this study 10% Zr is found to be the most compatible one with the Ti-6Al-4V matrix. However, in practice, 18Zr is the optimal brazing material for engineering applications due to the balance of the mechanical performance, cost, reliability and applicability.

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Jiang J, Hooper P, Li N, Luan Q, Hopper C, Ganapathy M, Lin Jet al., 2017, An integrated method for net-shape manufacturing components combining 3D additive manufacturing and compressive forming processes, International Conference on the Technology of Plasticity (ICTP 2017), Publisher: Elsevier, Pages: 1182-1187, ISSN: 1877-7058

Additive manufactured (AM) or 3D printed metallic components suffer poor and inconsistent mechanical properties due to the presence of a large number of micro-voids, residual stress and microstructure inhomogeneity. To overcome these problems, a new forming process has been proposed, which effectively combines AM and compressive forming. The aim of this study is to prove the feasibility of this newly proposed method by providing preliminary results. Thus, we compared the tensile performance of hot-forged additive manufactured stainless steel 316L samples to none-hot-forged additive manufactured ones. Significant improvement in mechanical properties has been found in the tensile tests as well hardness test. In addition, our EBSD characterized grain orientation maps at each stage of the process revealed the corresponding microstructure revolution which provides insights into underlying mechanistic.

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Zhao L, Yasmeen T, Gao P, Wei S, Bai Z, Jiang J, Lin Jet al., 2017, Mechanism-based constitutive equations for superplastic forming of TA15 with equiaxed fine grain structure, International Conference on the Technology of Plasticity, ICTP 2017, Pages: 1874-1879

© 2017 The Authors. Published by Elsevier Ltd. In this study, a set of mechanism-based viscoplastic constitutive equations has been established to predict the viscoplastic flow of TA15 alloy sheets in superplastic forming (SPF) processes. Internal variables are introduced in these constitutive equations to represent individual physical features of the material with equiaxed fine grain structure, such as dislocation density, isotropic hardening, recrystallization and dynamic recovery. 13 material constants in the constitutive equations have been determined from experimental data at a range of temperatures and strain rates. A gradient based optimisation method was applied for the calibration of the equations. Good agreement between the computational and experimental results has been obtained. These newly determined constitutive equations can be used for product and process design through superplastic forming processes.

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Jing Y, Su D, Yue X, Britton T, Jiang Jet al., 2017, The development of high strength brazing technique for Ti-6Al-4V using TiZrCuNi amorphous filler, Materials Characterization, Vol: 131, Pages: 526-531, ISSN: 1044-5803

The brazing joint of the Ti-6Al-4V alloy was produced with a designed brazing filler alloy and the optimized brazing temperature which is lower than the β-phase transformation of the matrix. The strength and the ductility of brazing joined Ti-6Al-4V samples were evaluated by conventional tensile tests with a DIC 2D–strain field measurement. The Widmanstätten microstructure with no voids or cracks or intermetallic compounds was found throughout the joint with a width of β-lamellar as ~ 1 μm. Due to the fine acicular α-Widmanstätten and β-lamellar, and the uniformly diffused filler elements throughout the entire joint, the strength of the joint was as much as the matrix. In addition, the hardness test results agreed well with the tensile strength tests. All fractures occurred in the matrix rather than the brazing joints. Furthermore, the maximum local tensile strain was measured as 20% in the matrix, while under the same stress, the brazing joint only reached 6.3% tensile plastic strain. Thus, the mechanical properties of the joint with the associated microstructure demonstrated that a successful brazing filler alloy has been developed for the Ti-6Al-4V alloy.

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Chen B, Jiang J, Dunne F, 2017, Microstructurally-sensitive fatigue crack nucleation in Ni-based single and oligo crystals, Journal of the Mechanics and Physics of Solids, Vol: 106, Pages: 15-33, ISSN: 1873-4782

An integrated experimental, characterisation and computational crystal plasticity study of cyclic plastic beam loading has been carried out for nickel single crystal (CMSX4) and oligocrystal (MAR002) alloys in order to assess quantitatively the mechanistic drivers for fatigue crack nucleation.The experimentally validated modelling provides knowledge of key microstructural quantities (accumulated slip, stress and GND density) at experimentally observed fatigue crack nucleation sites and it is shown that while each of these quantities is potentially important in crack nucleation, none of them in its own right is sufficient to be predictive. However, the local (elastic) stored energy density, measured over a length scale determined by the density of SSDs and GNDs, has been shown to predict crack nucleation sites in the single and oligocrystals tests. In addition, once primary nucleated cracks develop and are represented in the crystal model using XFEM, the stored energy correctly identifies where secondary fatigue cracks are observed to nucleate in experiments. This (Griffith-Stroh type) quantity also correctly differentiates and explains intergranular and transgranular fatigue crack nucleation.

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Rounthwaite N, McGilvery CM, Jiang J, Williams R, Giuliani F, Britton TBet al., 2017, A chemical and morphological study of diesel injector nozzle deposits - insights into their formation and growth mechanisms, SAE 2017 World Congress and Exhibition, Publisher: SAE International, Pages: 106-114, ISSN: 1946-3960

Modern diesel passenger car technology continues to develop rapidly in response to demanding emissions, performance, refinement, cost and fuel efficiency requirements. This has included the implementation of high pressure common rail fuel systems employing high precision injectors with complex injection strategies, higher hydraulic efficiency injector nozzles and in some cases <100µm nozzle hole diameters. With the trend towards lower diameter diesel injector nozzle holes and reduced cleaning through cavitation with higher hydraulic efficiency nozzles, it is increasingly important to focus on understanding the mechanism of diesel injector nozzle deposit formation and growth. In this study such deposits were analysed by cross-sectioning the diesel injector along the length of the nozzle hole enabling in-depth analysis of deposit morphology and composition change from the inlet to the outlet, using state-of-the-art electron microscopy techniques. Deposits produced in the injector nozzles of the industry standard fouling test (CEC F-98-08 DW10B bench engine) were compared with those formed in a vehicle driven on a chassis dynamometer, using a drive cycle more representative of real world vehicle conditions, to explore the effects of differing drive cycles and engine technologies. Fouling in all tests was accelerated with the addition of 1ppm zinc neodecanoate, as specified in the CEC DW10B test. This in-depth characterisation revealed a complex multi-layered system of deposits inside the diesel injector nozzle. Through analysing these layers the mechanisms enabling the initial deposit formation and growth can be postulated.

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Jiang J, Dunne F, Britton T, 2017, Toward predictive understanding of fatigue crack nucleation in Ni-based Superalloys, JOM, Vol: 69, Pages: 863-871, ISSN: 1047-4838

Predicting when and where materials fail is a holy grail for structural materials engineering. Development of a predictive capability in this domain will optimize the employment of existing materials, as well as rapidly enhance the uptake of new materials, especially in high-risk, high-value applications, such as aeroengines. In this article, we review and outline recent efforts within our research groups that focus on utilizing full-field measurement and calculation of micromechanical deformation in Ni-based superalloys. In paticular, we employ high spatial resolution digital image correlation (HR-DIC) to measure surface strains and a high-angular resolution electron backscatter diffraction technique (HR-EBSD) to measure elastic distortion, and we combine these with crystal plasticity finite element (CPFE) modeling. We target our studies within a system of samples that includes single, oligo, and polycrystals where the boundary conditions, microstructure, and loading configuration are precisely controlled. Coupling of experiment and simulation in this manner enables enhanced understanding of crystal plasticity, as demonstrated with case studies in deformation compatibility; spatial distributions of slip evolution; deformation patterning around microstructural defects; and ultimately development of predictive capability that probes the location of microstructurally sensitive fatigue cracks. We believe that these studies present a careful calibration and validation of our experimental and simulation-based approaches and pave the way toward new understanding of crack formation in engineering alloys.

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Dunne FPE, Guan Y, Britton TB, Jiang J, Chen B, Zou Jet al., 2016, Crystal Plasticity Modelling and HR-DIC Measurement of Slip Activation and Strain Localisation in Single and Oligo-crystal Ni Alloys under Fatigue, International Journal of Plasticity, Vol: 88, Pages: 70-88, ISSN: 0749-6419

Single crystal (CMSX4) and oligocrystal (MAR002) nickel have been studied using three-point beambending under conditions of cyclic loading. SEM images have enabled identification of slip activation,and high resolution digital image correlation has been utilized to quantify the developing strain fieldsand the strain localization in both single and oligocrystals in fatigue. The single and oligocrystalmicrostructures have been replicated within crystal plasticity finite element models and the fatigueloading analysed such that grain-by-grain comparisons of slip may be carried out. Single and multipleslip activation, slip localisation and microstructure-sensitive stress evolution have been examined.Single crystal bend fatigue gives rise to non-symmetric slip fields and localisation depending oncrystallographic orientation. Modelling correctly captures slip activation and the developing nonsymmetricslip fields. Oligocrystal slip is markedly heterogeneous, with grain misorientations drivingstrong variations, also reasonably captured by the model. Microstructure behaviour is found to varyspatially and include elastic-plastic hysteresis which is stable, and which undergoes mean stressrelaxation so that plastic shakedown occurs. Remarkable variations occur between locations eitherside of grain boundaries, providing appropriate opportunities for fatigue crack nucleation.

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Jiang J, Yang J, Zhang T, Wang Y, Dunne F, Britton Tet al., 2016, Microstructurally sensitive crack nucleation around inclusions in powder metallurgy nickel based superalloys, Acta Materialia, Vol: 117, Pages: 333-344, ISSN: 1359-6454

Nickel based superalloys are used in high strength, high value applications, such as gas turbine discs in aeroengines. In these applications the integrity of the disc is critical and therefore understanding crack initiation mechanisms is of high importance. With an increasing trend towards powder metallurgy routes for discs, sometimes unwanted non-metallic inclusions are introduced during manufacture. These inclusions vary in size from ~ 10 μm to 200 μm which is comparable to the grain size of the Nickel based superalloys. Cracks often initiate near these inclusions and the precise size, shape, location and path of these cracks are microstructurally sensitive. In this study, we focus on crack initiation at the microstructural length scale using a controlled three-point bend test, with the inclusion deliberately located within the tensile fibre of the beam. Electron backscatter diffraction (EBSD) is combined with high spatial resolution digital image correlation (HR-DIC) to explore full field plastic strain distributions, together with finite element modelling, to understand the micro-crack nucleation mechanisms. This full field information and controlled sample geometry enable us to systematically test crack nucleation criteria. We find that a combined stored energy and dislocation density provide promising results. These findings potentially facilitate more reliable and accurate lifing prediction tools to be developed and applied to engineering components.

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Peng Z, Tian G, Jiang J, Li M, Chen Y, Zou J, Dunne FPEet al., 2016, Mechanistic behaviour and modelling of creep in powder metallurgy FGH96 nickel superalloy, Materials Science and Engineering A, Vol: 676, Pages: 441-449, ISSN: 0921-5093

The creep properties of a nickel-based superalloy at 700 °C and 690 MPa resulting from differing aging heat treatments have been investigated. The heat treatments gave rise to significantly different tertiary γ′ precipitate distributions which in turn influence the propensity for precipitate shearing. The creep life was found to decrease with an increase of volume fraction of tertiary γ′. It is shown that the γ′ precipitates undergo shearing by matrix dislocations resulting in residual stacking faults which have been identified from TEM studies.A physically-based crystal slip model for creep deformation in FGH96 has been developed. A critical γ′ precipitate size is found to exist above which precipitate shearing occurs by strongly-coupled dislocations pairs. The critical size for FGH96 superalloy is less than 15 nm, which is smaller than most of the γ′ precipitates in the aged treated samples. A bimodal precipitate hardening model has been presented from which the slip strength resulting from differing heat treatments may be determined. Creep strain rate is found to decrease with increasing slip strength. The crystal slip model successfully captures the effect of heat treatment (in terms of γ′ precipitate distributions) on resulting creep behaviour in alloy FGH96.

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Wan VVC, Cuddihy MA, Jiang J, MacLachlan DW, Dunne FPEet al., 2016, An HR-EBSD and computational crystal plasticity investigation of microstructural stress distributions and fatigue hotspots in polycrystalline copper, Acta Materialia, Vol: 115, Pages: 45-57, ISSN: 1873-2453

High resolution EBSD studies on a deformed copper polycrystal have been carried out to quantify the microstructural residual stress distributions, and those of stress state including triaxiality of importance in defect nucleation studies. Crystal plasticity analysis of a representative, similarly textured, model polycrystal has been carried out showing that the experimental distributions of microstructural residual stress components, effective stress, hydrostatic stress and stress triaxiality are well captured.The crystal model enables point-wise microstructural Schmid factors to be calculated both globally (ie with respect to the macroscopic remote loading) and locally from full knowledge of the grain-level stress state. Significant differences are demonstrated such that global Schmid analysis tends to overestimate slip activity and the frequency of high Schmid factors, indicating that the local microstructural heterogeneity is significant and caution is necessary in interpreting polycrystal behaviour using global Schmid factors.A stored energy criterion for fatigue crack nucleation indicates that preferential sites for fatigue crack nucleation are local to grain boundaries (as opposed to triple junctions), and that hard-soft grain interfaces where high GND densities develop are preferable.

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Zhang T, Jiang J, Britton B, Shollock B, Dunne FPEet al., 2016, Crack nucleation using combined crystal plasticity modelling, high-resolution digital image correlation and high-resolution electron backscatter diffraction in a superalloy containing non-metallic inclusions under fatigue, Proceedings of the Royal Society A: Mathematical, Physical & Engineering Sciences, Vol: 472, ISSN: 1471-2946

A crystal plasticity finite-element model, which explicitly and directly represents the complex microstructures of a non-metallic agglomerate inclusion within polycrystal nickel alloy, has been developed to study the mechanistic basis of fatigue crack nucleation. The methodology is to use the crystal plasticity model in conjunction with direct measurement at the microscale using high (angular) resolution-electron backscatter diffraction (HR-EBSD) and high (spatial) resolution-digital image correlation (HR-DIC) strain measurement techniques. Experimentally, this sample has been subjected to heat treatment leading to the establishment of residual (elastic) strains local to the agglomerate and subsequently loaded under conditions of low cyclic fatigue. The full thermal and mechanical loading history was reproduced within the model. HR-EBSD and HR-DIC elastic and total strain measurements demonstrate qualitative and quantitative agreement with crystal plasticity results. Crack nucleation by interfacial decohesion at the nickel matrix/agglomerate inclusion boundaries is observed experimentally, and systematic modelling studies enable the mechanistic basis of the nucleation to be established. A number of fatigue crack nucleation indicators are also assessed against the experimental results. Decohesion was found to be driven by interface tensile normal stress alone, and the interfacial strength was determined to be in the range of 1270–1480 MPa.

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Britton TB, Jiang J, Vilata-Clemente A, Wallis D, Hansen L, Winkelmann A, Wilkinson AJet al., 2016, Tutorial: Crystal Orientations and EBSD – or which way is up?, Materials Characterization, Vol: 117, Pages: 113-126, ISSN: 1873-4189

Electron backscatter diffraction (EBSD) is an automated technique that can measure the orientation of crystals in a sample very rapidly. There are many sophisticated software packages that present measured data. Unfortunately, due to crystal symmetry and differences in the set-up of microscope and EBSD software, there may be accuracy issues when linking the crystal orientation to a particular microstructural feature. In this paper we outline a series of conventions used to describe crystal orientations and coordinate systems. These conventions have been used to successfully demonstrate that a consistent frame of reference is used in the sample, unit cell, pole figure and diffraction pattern frames of reference. We establish a coordinate system rooted in measurement of the diffraction pattern and subsequent linking to all other coordinate systems. A fundamental outcome of this analysis is to note that the beamshift coordinate system needs to be precisely defined for consistent 3D microstructure analysis. This is supported through a series of case studies examining particular features of the microscope settings and/or unambiguous crystallographic features. These case studies can be generated easily in most laboratories and represent an opportunity to demonstrate confidence in use of recorded orientation data. Finally, we include a simple software tool, written in both MATLAB® and Python, which the reader can use to compare consistency with their own microscope set-up and which may act a springboard for further offline analysis.

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Wan VVC, Jiang J, MacLachlan DW, Dunne FPEet al., 2016, Microstructure-sensitive fatigue crack nucleation in a polycrystalline Ni superalloy, International Journal of Fatigue, Vol: 90, Pages: 181-190, ISSN: 1879-3452

Large-grained polycrystalline Ni alloy RS5 has been tested in fatigue. Morphology and texture have been characterised using EBSD and utilised to construct representative 3D finite element crystal plasticity models. A stored energy criterion has been used to predict scatter in fatigue crack nucleation life and the results compared with experimental findings. Good quantitative prediction of experimental fatigue lives is obtained. The observed progressive increase in scatter with decreasing strain range is captured. The stored energies for fatigue crack nucleation determined for Ni alloy RS5 and ferritic steel and were found to be 13,300 J/m2 and 580 J/m2 respectively, showing very good consistency with the corresponding Griffith fracture energies of 48,700 J/m2 for Ni alloy and 1900 J/m2 for ferritic steel.Local microstructural variations are shown to influence corresponding grain-level stress–strain response. At the microstructural level, purely elastic, reversed plastic and ratcheting behaviour are all observed. In addition, plastic and elastic shakedown are also found to occur which depend upon features of the microstructure and the nature of the applied loading. These phenomena all influence fatigue crack nucleation.

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Jiang J, Zhang T, Dunne F, Britton Tet al., 2016, Deformation compatibility in a single crystalline Ni superalloy, Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences, Vol: 472, Pages: 1-24, ISSN: 1364-5021

Deformation in materials is often complex and requires rigorous understanding to predict engineering component lifetime. Experimental understanding of deformation requires utilization of advanced characterization techniques, such as high spatial resolution digital image correlation (HR-DIC) and high angular resolution electron backscatter diffraction (HR-EBSD), combined with clear interpretation of their results to understand how a material has deformed. In this study, we use HR-DIC and HR-EBSD to explore the mechanical behaviour of a single-crystal nickel alloy and to highlight opportunities to understand the complete deformations state in materials. Coupling of HR-DIC and HR-EBSD enables us to precisely focus on the extent which we can access the deformation gradient, F, in its entirety and uncouple contributions from elastic deformation gradients, slip and rigid body rotations. Our results show a clear demonstration of the capabilities of these techniques, found within our experimental toolbox, to underpin fundamental mechanistic studies of deformation in polycrystalline materials and the role of microstructure.

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Jiang J, Yang J, Zhang T, Dunne FPE, Britton TBet al., 2015, On the mechanistic basis of fatigue crack nucleation in Ni superalloy containing inclusions using high resolution electron backscatter diffraction, Acta Materialia, Vol: 97, Pages: 367-379, ISSN: 1873-2453

A series of interrupted three-point bend low-cycle fatigue tests were carried out on a powder metallurgy FHG96 nickel superalloy sample containing non-metallic inclusions. High resolution electron backscatter diffraction (HR-EBSD) was used to characterise the distribution and evolution of geometrically necessary dislocation (GND) density, residual stress and total dislocation density near a non-metallic inclusion. A systematic study of room temperature cyclic deformation is presented in which slip localisation, cyclic hardening, ratcheting and stabilisation occur, through to crack formation and microstructurally-sensitive propagation. Particular focus is brought to bear at the inclusion–matrix interface. Complex inhomogeneous deformation structures were directly observed from the first few loading cycles, and these structures were found not to vary significantly with increasing number of cycles. A clear link was observed between crack nucleation site and microstructurally-sensitive growth path and the spatially-resolved sites of extreme values of residual stress and GND density.

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Zhang T, Jiang J, Shollock BA, Ben Britton T, Dunne FPEet al., 2015, Slip localization and fatigue crack nucleation near a non-metallic inclusion in polycrystalline nickel-based superalloy, Materials Science and Engineering A: Structural Materials: Properties, Microstructure and Processing, Vol: 641, Pages: 328-339, ISSN: 1873-4936

Fatigue crack nucleation at a non-metallic agglomerate inclusion has been studied by high spatial resolution Digital Image Correlation (HR-DIC) and high angular resolution Electron Backscatter Diffraction (HR-EBSD). Spatial and temporal characterization and correlation of deformation with underlying microstructures has been performed, with distributions of plastic strain measured from HR-DIC; and residual stress and density of geometrically necessary dislocations (GND) measured from HR-EBSD. Initial residual stress and GND fields, as a consequence of differing thermal expansivities in the metallic and oxide phases, localized around the agglomerate have been quantified using HR-EBSD. The localization of the pre-existing stress and dislocation states appear to lead to early onset of plasticity upon subsequent mechanical loading. Heterogeneous distributions of plastic strain have been observed in the course of the fatigue test by HR-DIC. Crack nucleation via agglomerate/nickel interface decohesion and particle fracture has been demonstrated and this is correlated with the elevation in strain and dislocation density. The measurements of residual stress, strain, and dislocation density provide key information for the mechanisms of fatigue cracking and the development of damage nucleation criteria in these material systems.

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Jiang J, Ben Britton T, Wilkinson AJ, 2015, The orientation and strain dependence of dislocation structure evolution in monotonically deformed polycrystalline copper, INTERNATIONAL JOURNAL OF PLASTICITY, Vol: 69, Pages: 102-117, ISSN: 0749-6419

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• Citations: 72

Jiang J, Britton TB, Wilkinson AJ, 2015, Evolution of intragranular stresses and dislocation densities during cyclic deformation of polycrystalline copper, Acta Materialia, Vol: 94, Pages: 193-204, ISSN: 1873-2453

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Tong V, Jiang J, Wilkinson AJ, Ben Britton Tet al., 2015, The effect of pattern overlap on the accuracy of high resolution electron backscatter diffraction measurements, Ultramicroscopy, Vol: 155, Pages: 62-73, ISSN: 0304-3991

High resolution, cross-correlation-based, electron backscatter diffraction (EBSD) measures the variation of elastic strains and lattice rotations from a reference state. Regions near grain boundaries are often of interest but overlap of patterns from the two grains could reduce accuracy of the cross-correlation analysis. To explore this concern, patterns from the interior of two grains have been mixed to simulate the interaction volume crossing a grain boundary so that the effect on the accuracy of the cross correlation results can be tested. It was found that the accuracy of HR-EBSD strain measurements performed in a FEG-SEM on zirconium remains good until the incident beam is less than 18 nm from a grain boundary. A simulated microstructure was used to measure how often pattern overlap occurs at any given EBSD step size, and a simple relation was found linking the probability of overlap with step size.

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Wilkinson AJ, Tarleton E, Vilalta-Clemente A, Jiang J, Britton TB, Collins DMet al., 2014, Measurement of probability distributions for internal stresses in dislocated crystals, APPLIED PHYSICS LETTERS, Vol: 105, ISSN: 0003-6951

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• Citations: 28

Wilkinson AJ, Britton TB, Jiang J, Karamched PSet al., 2014, A review of advances and challenges in EBSD strain mapping, 13th European Workshop of the European-Microbeam-Analysis-Society on Modern Developments and Applications in Microbeam Analysis (EMAS), Publisher: IOP PUBLISHING LTD, ISSN: 1757-8981

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• Citations: 37

Britton TB, Jiang J, Clough R, Tarleton E, Kirkland AI, Wilkinson AJet al., 2013, Assessing the precision of strain measurements using electron backscatter diffraction - Part 2: Experimental demonstration, ULTRAMICROSCOPY, Vol: 135, Pages: 136-141, ISSN: 0304-3991

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• Citations: 17

Britton TB, Jiang J, Clough R, Tarleton E, Kirkland AI, Wilkinson AJet al., 2013, Assessing the precision of strain measurements using electron backscatter diffraction - part 1: Detector assessment, ULTRAMICROSCOPY, Vol: 135, Pages: 126-135, ISSN: 0304-3991

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• Citations: 32

Jiang J, Britton TB, Wilkinson AJ, 2013, Evolution of dislocation density distributions in copper during tensile deformation, ACTA MATERIALIA, Vol: 61, Pages: 7227-7239, ISSN: 1359-6454

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• Citations: 199

Ben Britton T, Jiang J, Karamched PS, Wilkinson AJet al., 2013, Probing Deformation and Revealing Microstructural Mechanisms with Cross-Correlation-Based, High-Resolution Electron Backscatter Diffraction, JOM, Vol: 65, Pages: 1245-1253, ISSN: 1047-4838

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• Citations: 21

Jiang J, Britton TB, Wilkinson AJ, 2013, Mapping type III intragranular residual stress distributions in deformed copper polycrystals, ACTA MATERIALIA, Vol: 61, Pages: 5895-5904, ISSN: 1359-6454

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• Citations: 40

Jiang J, Britton TB, Wilkinson AJ, 2013, Measurement of geometrically necessary dislocation density with high resolution electron backscatter diffraction: Effects of detector binning and step size, ULTRAMICROSCOPY, Vol: 125, Pages: 1-9, ISSN: 0304-3991

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• Citations: 195

Jiang J, Britton TB, Wilkinson AJ, 2012, Accumulation of geometrically necessary dislocations near grain boundaries in deformed copper, PHILOSOPHICAL MAGAZINE LETTERS, Vol: 92, Pages: 580-588, ISSN: 0950-0839

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• Citations: 46