| People | Locations | Statistics |
|---|---|---|
| Naji, M. |
| |
| Motta, Antonella |
| |
| Aletan, Dirar |
| |
| Mohamed, Tarek |
| |
| Ertürk, Emre |
| |
| Taccardi, Nicola |
| |
| Kononenko, Denys |
| |
| Petrov, R. H. | Madrid |
|
| Alshaaer, Mazen | Brussels |
|
| Bih, L. |
| |
| Casati, R. |
| |
| Muller, Hermance |
| |
| Kočí, Jan | Prague |
|
| Šuljagić, Marija |
| |
| Kalteremidou, Kalliopi-Artemi | Brussels |
|
| Azam, Siraj |
| |
| Ospanova, Alyiya |
| |
| Blanpain, Bart |
| |
| Ali, M. A. |
| |
| Popa, V. |
| |
| Rančić, M. |
| |
| Ollier, Nadège |
| |
| Azevedo, Nuno Monteiro |
| |
| Landes, Michael |
| |
| Rignanese, Gian-Marco |
|
Holmestad, Randi
Norwegian University of Science and Technology
in Cooperation with on an Cooperation-Score of 37%
Topics
Publications (51/51 displayed)
- 2024On the precipitation and transformation kinetics of precipitationhardening steel X5CrNiCuNb16-4 in a wide range of heating and cooling ratescitations
- 2024Atomic structure of clusters and GP-zones in an Al-Mg-Si alloycitations
- 2024On the precipitation and transformation kinetics of precipitation-hardening steel X5CrNiCuNb16-4 in a wide range of heating and cooling ratescitations
- 2024Al-Cu intermetallic phase growth in hybrid metal extrusion & bonding welds exposed to isothermal annealing or direct current cycling
- 2024Accelerating precipitation hardening by natural aging in a 6082 Al-Mg-Si alloycitations
- 2024Effects of grain boundary chemistry and precipitate structure on intergranular corrosion in Al-Mg-Si alloys doped with Cu and Zncitations
- 2023Atomic Structure of Hardening Precipitates in Al-Mg-Si Alloys: Influence of Minor Additions of Cu and Zncitations
- 2023Multi-material Joining of an Aluminum Alloy to Copper, Steel, and Titanium by Hybrid Metal Extrusion & Bondingcitations
- 2022An improved modelling framework for strength and work hardening of precipitate strengthened Al–Mg–Si alloyscitations
- 2022Local mechanical properties and precipitation inhomogeneity in large-grained Al–Mg–Si alloycitations
- 2022The Effect of Small Additions of Fe and Heavy Deformation on the Precipitation in an Al–1.1Mg–0.5Cu–0.3Si At. Pct Alloycitations
- 2022On intermetallic phases formed during interdiffusion between aluminium alloys and stainless steelcitations
- 2022Influence of natural aging and ramping before artificial aging on the microstructure of two different 6xxx alloyscitations
- 2022Effect of Multiply Twinned Ag(0) Nanoparticles on Photocatalytic Properties of TiO2 Nanosheets and TiO2 Nanostructured Thin Filmscitations
- 2021Interface Microstructure and Tensile Properties of a Third Generation Aluminium-Steel Butt Weld Produced Using the Hybrid Metal Extrusion & Bonding (HYB) Processcitations
- 2021Studying GPI zones in Al-Zn-Mg alloys by 4D-STEMcitations
- 2021Effect of pre-deformation on age-hardening behaviors in an Al-Mg-Cu alloycitations
- 2021On the microstructural origins of improvements in conductivity by heavy deformation and ageing of Al-Mg-Si alloy 6101citations
- 2021Linking mechanical properties to precipitate microstructure in three Al-Mg-Si(-Cu) alloyscitations
- 2020Grain boundary structures and their correlation with intergranular corrosion in an extruded Al-Mg-Si-Cu alloycitations
- 2020Stress Corrosion Cracking in an Extruded Cu-Free Al-Zn-Mg Alloycitations
- 2020Stress Corrosion Cracking in an Extruded Cu-Free Al-Zn-Mg Alloy
- 2020First principle calculations of pressure dependent yielding in solute strengthened aluminium alloyscitations
- 2020Multislice image simulations of sheared needle‐like precipitates in an Al‐Mg‐Si alloycitations
- 2020Comparing intergranular corrosion in Al‐Mg‐Si‐Cu alloys with and without α‐Al(Fe,Mn,Cu)Si particlescitations
- 2020Copper enrichment on aluminium surfaces after electropolishing and its effect on electron imaging and diffractioncitations
- 2020Microstructural and mechanical characterisation of a second generation hybrid metal extrusion & bonding aluminium-steel butt jointcitations
- 2019Nano-scale characterisation of sheared β” precipitates in a deformed Al-Mg-Si alloycitations
- 2019In situ heating TEM observations of evolving nanoscale Al‐Mg‐Si‐Cu precipitatescitations
- 2019Precipitation in an extruded AA7003 aluminium alloy: Observations of 6xxx-type hardening phasescitations
- 2019The Effect of Elastic Strain and Small Plastic Deformation on Tensile Strength of a Lean Al–Mg–Si Alloycitations
- 2018The evolution of precipitate crystal structures in an Al-Mg-Si(-Cu) alloy studied by a combined HAADF-STEM and SPED approachcitations
- 2018The correlation between intergranular corrosion resistance and copper content in the precipitate microstructure in an AA6005A alloycitations
- 2018Lattice rotations in precipitate free zones in an Al-Mg-Si alloycitations
- 2018Crystallographic relationships of T-/S-phase aggregates in an Al–Cu–Mg–Ag alloycitations
- 2017Atomistic details of precipitates in lean Al–Mg–Si alloys with trace additions of Ag and Ge studied by HAADF-STEM and DFTcitations
- 2016Elemental electron energy loss mapping of a precipitate in a multi-component aluminium alloycitations
- 2016Assessing electron beam sensitivity for SrTiO3 and La0.7Sr0.3MnO3 using electron energy loss spectroscopycitations
- 2016Effect of polar (111)-oriented SrTiO3 on initial perovskite growthcitations
- 2016The effects and behaviour of Li and Cu alloying agents in lean Al-Mg-Si alloyscitations
- 2015A hybrid aluminium alloy and its zoo of interacting nano-precipitatescitations
- 2015Structural investigation of epitaxial LaFeO_3 thin films on (111) oriented SrTiO_3 by transmission electron microscopycitations
- 2015Structural modifications and electron beam damage in aluminium alloy precipitate θ'-Al2Cucitations
- 2014Atomic-resolution electron energy loss studies of precipitates in an Al-Mg-Si-Cu-Ag alloycitations
- 2014Aberration-corrected HAADF-STEM investigations of precipitate structures in Al-Mg-Si alloys with low Cu additionscitations
- 2014Clustering and Vacancy Behavior in High- and Low-Solute Al-Mg-Si Alloyscitations
- 2014The effects of quench rate and pre-deformation on precipitation hardening in Al–Mg–Si alloys with different Cu amountscitations
- 2013How calcium prevents precipitation hardening in Al–Mg–Si alloyscitations
- 2013Muon kinetics in heat treated Al (–Mg)(–Si) alloyscitations
- 2012Reversal of the negative natural aging effect in Al-Mg-Si alloyscitations
- 2012Probing defects in Al-Mg-Si alloys using muon spin relaxationcitations
Places of action
| Organizations | Location | People |
|---|
article
Multislice image simulations of sheared needle‐like precipitates in an Al‐Mg‐Si alloy
Abstract
<jats:title>Summary</jats:title><jats:sec><jats:label /><jats:p>The image contrast of sheared needle‐like <jats:inline-graphic xmlns:xlink="http://www.w3.org/1999/xlink" xlink:href="graphic/jmi12901-math-0001.png" xlink:title="urn:x-wiley:00222720:media:jmi12901:jmi12901-math-0001" /> precipitates in the Al‐Mg‐Si alloy system is investigated with respect to shear‐plane positions, the number of shear‐planes, and the active matrix slip systems through multislice transmission electron microscopy image simulations and the frozen phonon approximation. It is found that annular dark field scanning transmission electron microscopy (ADF STEM) images are mostly affected by shear‐planes within a distance ∼6–18 unit cells from the specimen surface, whereas about 5–10 equidistant shear‐planes are required to produce clear differences in HRTEM images. The contrast of the images is affected by the Burgers vector of the slip, but not the slip plane. The simulation results are discussed and compared to experimental data.</jats:p></jats:sec><jats:sec><jats:title>Lay Description</jats:title><jats:p>Pure aluminium is too soft to be viable in most structural applications, but this may be remedied by alloying the metal with various elements. Adding small amounts of silicon and magnesium to pure aluminium allows small particles to precipitate during heat treatment. These precipitates resist plastic deformation and can increase the strength of the alloy and make it viable for a range of industrial applications, such as automotive door panels and load‐bearing profiles. However, if subjected to large loads, the precipitates are sheared and the strength of the alloy changes dynamically. Designing safe products such as cars or buildings require physically based predictions on this dynamical change. Developing models that can provide such predictions depend in turn on experimental observations of the shearing process. Because the precipitates are nm long, experimental observations must be done by transmission electron microscopy. However, understanding these results sometimes require computer simulations of atomic models. In this work, we have performed image simulations of various models of sheared precipitates and compared the results with earlier experiments. The simulations indicate that certain conditions must be met for the sheared precipitates to appear different from unsheared precipitates. These conditions are most likely to be met if precipitates are sheared several times in a relatively homogeneous manner. This is important for two reasons. First, a localized shearing process would lead to large dynamical changes in precipitate strength during deformation, and in turn drastically reduce the work hardening of the alloy. Secondly, a localized shearing process would have promoted earlier fracture and failure of the alloy during deformation. Finally, our results also show how different slip directions influences the images of precipitates. In the future, these influences can be used to further understand the shearing process of these precipitates. Hence, our results can be used to improve model predictions of strength, work hardening, and fracture. In turn, this may improve alloy design and reduce the use of prototype testing in, e.g. the automotive industry.</jats:p></jats:sec>