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391 results on '"Cocks, Alan"'

1. Vacancies making jerky flow in complex alloys

Author

Liang, Zhida, Liu, Fengxian, Wang, Li, You, Zihan, Zhong, Fanqi, Cocks, Alan, and Pyczak, Florian

Subjects
Condensed Matter - Materials Science
Abstract

Longevity of materials, especially alloys, is crucial for enhancing the sustainability and efficiency of various applications, including gas turbines. Jerky flow, also known as dynamic strain aging effect, can indeed have a significant impact on the fatigue life of high-temperature components in gas turbines. In general, three jerky flow types, i.e., A, B and C, existed in superalloys. Type A and B, occurring at low temperature, were proved to be caused by interstitial elements, such as carbon. However, Type C serration at high temperature has not been verified directly and remains unresolved, which was unanimously agreed it is caused by the interaction between solute elements and dislocations. In this study, our new discovery challenged this mainstream axiom. We proposed that vacancies play a dominant role in inducing jerky flow instead of solute atoms. By transmission electron microscopy, we observed directly that dislocations are pinned by vacancy-type dislocation loops (PDLs) or dipoles. Our findings suggest that vacancies located at dislocation jogs are primarily responsible for pinning and unpinning of superlattice dislocations. As dislocations move and interact with vacancies, PDLs or dipoles are left behind in their path. This pinning and unpinning process is repeated as successive dislocations encounter the newly formed PDLs or dipoles, leading to the recurring fluctuations in the stress, i.e., serrated flow. Additionally, antisite defects created by Co, Cr and Ti sitting on Ni positions is postulated to facilitate vacancy formation and migration towards dislocations via nearest neighbor jumps. This study provides a new avenue to show how future alloy design can improve the fatigue life of superalloys in extreme environments.

Published
2024

3. On the influence of alloy composition on the additive manufacturability of Ni-based superalloys

Author

Ghoussoub, Joseph N., Tang, Yuanbo T., Dick-Cleland, William J B., Németh, André A. N., Gong, Yilun, McCartney, D. Graham, Cocks, Alan C. F., and Reed, Roger C.

Subjects
Condensed Matter - Materials Science
Abstract

The susceptibility of nickel-based superalloys to processing-induced crack formation during laser powder-bed additive manufacturing is studied. Twelve different alloys -- some of existing (heritage) type but also other newly-designed ones -- are considered. A strong inter-dependence of alloy composition and processability is demonstrated. Stereological procedures are developed to enable the two dominant defect types found -- solidification cracks and solid-state ductility dip cracks -- to be distinguished and quantified. Differential scanning calorimetry, creep stress relaxation tests at 1000$^\circ$C and measurements of tensile ductility at 800$^\circ$C are used to interpret the effects of alloy composition. A model for solid-state cracking is proposed, based on an incapacity to relax the thermal stress arising from constrained differential thermal contraction; its development is supported by experimental measurements using a constrained bar cooling test. A modified solidification cracking criterion is proposed based upon solidification range but including also a contribution from the stress relaxation effect. This work provides fundamental insights into the role of composition on the additive manufacturability of these materials.

Published
2021
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4. Creep-fatigue interactions in a polycrystalline structural material under typical high-temperature power plant operating conditions

Author

Petkov, Markian, Chevalier, Marc, Dean, David, and Cocks, Alan C. F.

Subjects
Condensed Matter - Materials Science
Abstract

A micromechanical model at the microscale within a crystal plasticity self-consistent model, is used to analyse loading histories in Type 316H stainless steel, common to structural components in high-temperature power plants. The study compares the SCM predictions on changes in mechanical behaviour and creep properties to analyses via the UK R5 structural assessment code. Plant-relevant cyclic-creep histories in Type 316H stainless steel at 550C are examined with focus on the estimation of accumulated creep strain. This aims to quantify how better understanding of creep deformation under cyclic loading can inform R5 code life assessment methods, which are strain based. The effect of cyclic plasticity on primary and secondary creep is quantified. The levels of creep strain accumulated during different dwells, following loading from different macroscopic stress states, is also evaluated and link is made to experimental observations in explaining the response. The impact of displacement- and load-controlled dwells on the evolution of the cyclic hysteresis loop is examined which revealed how different assumptions for creep strain accumulation could employ information from SCM results to reduce uncertainty. It also provides guidance in the development of interpolation frameworks for structural parameters, based on the SCM results which could be used directly in structural assessment and design approaches to estimate the accumulation of inelastic strain with a lower degree of conservatism., Comment: Keywords: crystal plasticity, cyclic hardening, creep-fatigue, micromechanical, structural assessment. 19 Pages, 14 Figures, 5 Tables

Published
2021

5. Evaluation of local stress state due to grain-boundary sliding during creep within a crystal plasticity finite element multi-scale framework

Author

Petkov, Markian, Elmukashfi, Elsiddig, Tarleton, Edmund, and Cocks, Alan C. F.

Subjects
Condensed Matter - Materials Science, Mathematics - Numerical Analysis
Abstract

Previous studies demonstrate that grain-boundary sliding could accelerate creep rate and give rise to large internal stresses that can lead to damage development, e.g. formation of wedge cracks. The present study provides more insight into the effects of grain-boundary sliding (GBS) on the deformation behaviour of realistic polycrystalline aggregates during creep, through the development of a computational framework which combines: i) the use of interface elements for sliding at grain boundaries, and ii) special triple point (in 2D) or triple line (in 3D) elements to prevent artificial dilation at these locations in the microstructure with iii) a physically-based crystal plasticity constitutive model for time-dependent inelastic deformation of the individual grains. Experimental data at various scales is used to calibrate the framework and compare with model predictions. We pay particular consideration to effects of grain boundary sliding during creep of Type 316 stainless steel, which is used extensively in structural components of the UK fleet of Advanced Gas Cooled Nuclear Reactors (AGRs). It is found that the anisotropic deformation of the grains and the mismatch in crystallographic orientation between neighbouring grains play a significant role in determining the extent of sliding on a given boundary. Their effect on the development of stress within the grains, particularly at triple grain junctions, and the increase in axial stress along transverse boundaries are quantified. The article demonstrates that the magnitude of the stress along the facets is highly-dependent on the crystallographic orientations of the neighbouring grains and the relative amount of sliding. Boundaries, transverse to the applied load tend to carry higher normal stresses of the order of 100-180 MPa, in cases where the neighbouring grains consist of plastically-harder crystallographic orientations., Comment: Keywords: grain boundary sliding, creep, interface, polycrystalline, triple grain junction, crystal plasticity. 21 Pages, 16 Figures, 2 Tables

Published
2021

7. Characterisation of slip and twin activity using digital image correlation and crystal plasticity finite element simulation: Application to orthorhombic $\alpha$-uranium

Author

Grilli, Nicolò, Earp, Philip, Cocks, Alan C. F., Marrow, James, and Tarleton, Edmund

Subjects
Condensed Matter - Materials Science, Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Calibrating and verifying crystal plasticity material models is a significant challenge, particularly for materials with a number of potential slip and twin systems. Here we use digital image correlation on coarse-grained $\alpha$-uranium during tensile testing in conjunction with crystal plasticity finite element simulations. This approach allows us to determine the critical resolved shear stress, and hardening rate of the different slip and twin systems. The constitutive model is based on dislocation densities as state variables and the simulated geometry is constructed from electron backscatter diffraction images that provide shape, size and orientation of the grains, allowing a direct comparison between virtual and real experiments. An optimisation algorithm is used to find the model parameters that reproduce the evolution of the average strain in each grain as the load is increased. A tensile bar, containing four grains aligned with the load direction, is used to calibrate the model with eight unknown parameters. The approach is then independently validated by simulating the strain distribution in a second tensile bar. Different mechanisms for the hardening of the twin systems are evaluated. The latent hardening of the most active twin system turns out to be determined by coplanar twins and slip. The hardening rate of the most active slip system is lower than in fine-grained $\alpha$-uranium. The method developed in the present research can be applied to identify the critical resolved shear stress and hardening parameters of other coarse-grained materials.

Published
2020
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9. The influence of hydrogen core force shielding on dislocation junctions in iron

Author

Yu, Haiyang, Katzarov, Ivaylo H., Paxton, Anthony T., Cocks, Alan C. F., and Tarleton, Edmund

Subjects
Condensed Matter - Materials Science
Abstract

The influence of hydrogen on dislocation junctions was analysed by incorporating a hydrogen dependent core force into nodal based discrete dislocation dynamics. Hydrogen reduces the core energy of dislocations, which reduces the magnitude of the dislocation core force. We refer to this as hydrogen core force shielding, as it is analogous to hydrogen elastic shielding but occurs at much lower hydrogen concentrations. The dislocation core energy change due to hydrogen was calibrated at the atomic scale accounting for the nonlinear inter-atomic interactions at the dislocation core, giving the model a sound physical basis. Hydrogen was found to strengthen binary junctions and promote the nucleation of dislocations from triple junctions. Simulations of microcantilever bend tests with hydrogen core force shielding showed an increase in the junction density and subsequent hardening. These simulations were performed at a small hydrogen concentration realistic for bcc iron.

Published
2019
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13. Discrete dislocation plasticity HELPs understand hydrogen effects in bcc materials

Author

Yu, Haiyang, Cocks, Alan, and Tarleton, Edmund

Subjects
Condensed Matter - Materials Science
Abstract

In an attempt to bridge the gap between atomistic and continuum plasticity simulations of hydrogen in iron, we present three dimensional discrete dislocation plasticity simulations incorporating the hydrogen elastic stress and a hydrogen dependent dislocation mobility law. The hydrogen induced stress is incorporated following the formulation derived by Gu and El-Awady (2018) which here we extend to a finite boundary value problem, a microcantilever beam, via the superposition principle. The hydrogen dependent mobility law is based on first principle calculations by Katzarov et al. (2017) and was found to promote dislocation generation and enhance slip planarity at a bulk hydrogen concentration of 0.1 appm; which is typical for bcc materials. The hydrogen elastic stress produced the same behaviour, but only when the bulk concentration was extremely high. In a microcantilever, hydrogen was found to promote dislocation activity which lowered the flow stress and generated more pronounced slip steps on the free surfaces. These observations are consistent with the hydrogen enhanced localized plasticity (HELP) mechanism, and it is concluded that both the hydrogen elastic stress and hydrogen increased dislocation mobility are viable explanations for HELP. However it is the latter that dominates at the low concentrations typically found in bcc metals., Comment: 24 pages 20 figures

Published
2018
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44. Ice-lens formation and geometrical supercooling in soils and other colloidal materials

Author

Style, Robert W., Peppin, Stephen S. L., Cocks, Alan C. F., and Wettlaufer, John S.

Subjects
Physics - Geophysics, Condensed Matter - Soft Condensed Matter
Abstract

We present a new, physically-intuitive model of ice-lens formation and growth during the freezing of soils and other dense, particulate suspensions. Motivated by experimental evidence, we consider the growth of an ice-filled crack in a freezing soil. At low temperatures, ice in the crack exerts large pressures on the crack walls that will eventually cause the crack to split open. We show that the crack will then propagate across the soil to form a new lens. The process is controlled by two factors: the cohesion of the soil, and the geometrical supercooling of the water in the soil; a new concept introduced to measure the energy available to form a new ice lens. When the supercooling exceeds a critical amount (proportional to the cohesive strength of the soil) a new ice lens forms. This condition for ice-lens formation and growth does not appeal to any ad hoc, empirical assumptions, and explains how periodic ice lenses can form with or without the presence of a frozen fringe. The proposed mechanism is in good agreement with experiments, in particular explaining ice-lens pattern formation, and surges in heave rate associated with the growth of new lenses. Importantly for systems with no frozen fringe, ice-lens formation and frost heave can be predicted given only the unfrozen properties of the soil. We use our theory to estimate ice-lens growth temperatures obtaining quantitative agreement with the limited experimental data that is currently available. Finally we suggest experiments that might be performed in order to verify this theory in more detail. The theory is generalizable to complex natural-soil scenarios, and should therefore be useful in the prediction of macroscopic frost heave rates., Comment: Submitted to PRE

Published
2011
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