Grain size dependence of slip band length with plastic deformation in aluminum alloy.

There are several severe plastic deformation processes that transform the material from microsized grains to the nanosized grains under large deformations. The grain size of a macrostructure is generally 300 μm. Following severe plastic deformation it can be reached a grain size of 200 nm and even less up to 50 nm. These structures are called ultrafine grained materials with nanostructured organization of the grains. There are severe plastic deformation processes like equal angular channel, high pressure torsion which lead to a 200 nm grain size, respectively 100 nm grain size. Basically, these processes have a common point namely to act on the original sized material so that an extreme deformation to be produced. The severe plastic deformation processes developed until now are empirically-based and the modeling of them requires more understanding of how the materials deform. The macrostructural material models do not fit the behavior of the nanostructured materials exhibiting simultaneously high strength and ductility. The existent material laws need developments which consider multi-scale analysis. In this context, the present paper presents a laboratory method to obtain ultrafine grains of an aluminum alloy (Al-Mg) that allows the microstructure observations and furthermore the identification of the stress–strain response under loadings. The work is divided into (i) processing of the ultrafine-grained aluminum alloy using a laboratory-scale process named in-plane controlled multidirectional shearing process, (ii) crystallographic analysis of the obtained material structure, (iii) tensile testing of the ultrafine-grained aluminum specimens for obtaining the true stress-strain behavior. Thus, the microscale phenomena are explained with respect to the external loads applied to the aluminum alloy. The proposed multi-scale analysis gives an accurate prediction of the mechanical behavior of the ultrafine-grained materials that can be further applied to finite element modeling of the microforming processes.

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Grain size dependence of the plastic deformation kinetics in Cu

Materials Science and Engineering A ◽

10.1016/s0921-5093(02)00238-1 ◽

2003 ◽

Vol 341 (1-2) ◽

pp. 216-228 ◽

Cited By ~ 231

Author(s):

Hans Conrad

Keyword(s):

Plastic Deformation ◽

Grain Size ◽

Size Dependence ◽

Deformation Kinetics

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Effect of Melt Intensive Homogenization on Solidification Microstructure of 7075 Aluminium Alloy by Twin-Screw Stirring

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.750-752.771 ◽

2013 ◽

Vol 750-752 ◽

pp. 771-775

Author(s):

Zhi Hua Gao ◽

Jun Xu ◽

Guo Jun Liu ◽

Zhi Feng Zhang ◽

Men Gou Tang ◽

...

Keyword(s):

Grain Size ◽

Aluminum Alloy ◽

Grain Refinement ◽

Size Dependence ◽

Test Procedure ◽

Standard Test ◽

7075 Aluminum Alloy ◽

Pouring Temperature ◽

Screw Machine ◽

Twin Screw

Intensive melt shearing achieved using a twin-screw machine was applied to the 7075 aluminum alloy melt to investigate its effects on grain refinement. Alloy melt without and with melt shearing was cast in the standard test procedure mould, and the effects of casting temperature, shearing time and shearing intensity on microstructures were analyzed. The results show that the intensive melt shearing exhibits superior grain refinement and remarkable structure homogeneity. Without shearing, the grain size increases significantly with the increase in pouring temperature, while with intensive melt shearing the grain size is finer at all the pouring temperatures tested with a reduced grain size dependence on the pouring temperature. With the shearing time or shearing intensity increasing, the grain size of the equiaxed primary α (Al) phase decreases on the sample microstructures, and the grain distributions trend to become more fine and non-dendritical.

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Grain-size dependence of plastic deformation in nanocrystalline Fe

Journal of Applied Physics ◽

10.1063/1.1569035 ◽

2003 ◽

Vol 93 (11) ◽

pp. 9282-9286 ◽

Cited By ~ 60

Author(s):

D. Jang ◽

M. Atzmon

Keyword(s):

Plastic Deformation ◽

Grain Size ◽

Size Dependence

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Structural Transformations and Mechanical Properties of Metastable Austenitic Steel under High Temperature Thermomechanical Treatment

Metals ◽

10.3390/met11040645 ◽

2021 ◽

Vol 11 (4) ◽

pp. 645

Author(s):

Igor Litovchenko ◽

Sergey Akkuzin ◽

Nadezhda Polekhina ◽

Kseniya Almaeva ◽

Evgeny Moskvichev

Keyword(s):

Plastic Deformation ◽

Grain Size ◽

High Temperature ◽

Austenitic Steel ◽

Structural Transformations ◽

Initial State ◽

Twin Boundaries ◽

Metastable Austenitic Steel ◽

Average Grain Size ◽

Heating Up

The effect of high-temperature thermomechanical treatment on the structural transformations and mechanical properties of metastable austenitic steel of the AISI 321 type is investigated. The features of the grain and defect microstructure of steel were studied by scanning electron microscopy with electron back-scatter diffraction (SEM EBSD) and transmission electron microscopy (TEM). It is shown that in the initial state after solution treatment the average grain size is 18 μm. A high (≈50%) fraction of twin boundaries (annealing twins) was found. In the course of hot (with heating up to 1100 °C) plastic deformation by rolling to moderate strain (e = 1.6, where e is true strain) the grain structure undergoes fragmentation, which gives rise to grain refining (the average grain size is 8 μm). Partial recovery and recrystallization also occur. The fraction of low-angle misorientation boundaries increases up to ≈46%, and that of twin boundaries decreases to ≈25%, compared to the initial state. The yield strength after this treatment reaches up to 477 MPa with elongation-to-failure of 26%. The combination of plastic deformation with heating up to 1100 °C (e = 0.8) and subsequent deformation with heating up to 600 °C (e = 0.7) reduces the average grain size to 1.4 μm and forms submicrocrystalline fragments. The fraction of low-angle misorientation boundaries is ≈60%, and that of twin boundaries is ≈3%. The structural states formed after this treatment provide an increase in the strength properties of steel (yield strength reaches up to 677 MPa) with ductility values of 12%. The mechanisms of plastic deformation and strengthening of metastable austenitic steel under the above high-temperature thermomechanical treatments are discussed.

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A Physical-Based Plane Stress Constitutive Model for High Strength AA7075 under Hot Forming Conditions

Metals ◽

10.3390/met11020314 ◽

2021 ◽

Vol 11 (2) ◽

pp. 314

Author(s):

Fulong Chen ◽

Haitao Qu ◽

Wei Wu ◽

Jing-Hua Zheng ◽

Shuguang Qu ◽

...

Keyword(s):

Grain Size ◽

Aluminum Alloy ◽

Plane Stress ◽

Metal Forming ◽

Electron Backscatter Diffraction ◽

High Strength ◽

Material Model ◽

Hot Forming ◽

Industrial Processing ◽

Average Grain Size

Physicallybased constitutive equations are increasingly used for finite element simulations of metal forming processes due to the robust capability of modelling of underlying microstructure evolutions. However, one of thelimitations of current models is the lack of practical validation using real microstructure data due to the difficulties in achieving statistically meaningful data at a sufficiently large microstructure scale. Particularly, dislocation density and grain size governing the hardening in sheet deformation are of vital importance and need to be precisely quantified. In this paper, a set of dislocation mechanics-based plane stress material model is constructed for hot forming aluminum alloy. This material model is applied to high strength 7075 aluminum alloy for the prediction of the flow behaviorsconditioned at 300–400 °C with various strain rates. Additionally, an electron backscatter diffraction (EBSD) technique was applied to examine the average grain size and geometrical necessary dislocation (GND) density evolutions, enabling both macro- and micro- characteristics to be successfully predicted. In addition, to simulate the experienced plane stress states in sheet metal forming, the calibrated model is further extended to a plane stress stateto accuratelypredict the forming limits under hot conditions.The comprehensively calibrated material model could be used for guidinga better selection of industrial processing parameters and designing process windows, taking into account both the formed shape as well as post formed microstructure and, hence, properties.

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Finite element modelling of microstructural changes during equal channel angular drawing of pure aluminium

The International Journal of Advanced Manufacturing Technology ◽

10.1007/s00170-021-06972-0 ◽

2021 ◽

Author(s):

Serafino Caruso ◽

Stano Imbrogno

Keyword(s):

Plastic Deformation ◽

Grain Size ◽

Finite Element ◽

Size Variation ◽

Fe Model ◽

Pure Aluminium ◽

Continuous Dynamic Recrystallization ◽

Research Activities ◽

Hardness Change ◽

Continuous Dynamic

AbstractGrain refinement by severe plastic deformation (SPD) techniques, as a mechanism to control microstructure (recrystallization, grain size changes,…) and mechanical properties (yield strength, ultimate tensile strength, strain, hardness variation…) of pure aluminium conductor wires, is a topic of great interest for both academic and industrial research activities. This paper presents an innovative finite element (FE) model able to describe the microstructural evolution and the continuous dynamic recrystallization (CDRX) that occur during equal channel angular drawing (ECAD) of commercial 1370 pure aluminium (99.7% Al). A user subroutine has been developed based on the continuum mechanical model and the Hall-Petch (H-P) equations to predict grain size variation and hardness change. The model is validated by comparison with the experimental results and a predictive analysis is conducted varying the channel die angles. The study provides an accurate prediction of both the thermo-mechanical and the microstructural phenomena that occur during the process characterized by large plastic deformation.

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Size-Dependence of Photoluminescence Property of ZnO Nanoparticles

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.887-888.143 ◽

2014 ◽

Vol 887-888 ◽

pp. 143-146 ◽

Cited By ~ 2

Author(s):

Xiao Fang Wang ◽

Yun Liang Fang ◽

Tian Le Li ◽

Fu Juan Wang

Keyword(s):

Grain Size ◽

Lower Energy ◽

Size Dependence ◽

Surface States ◽

Photoluminescence Property ◽

Precipitation Method ◽

Pl Spectra ◽

Broadband Emission ◽

Band Emission ◽

20 Nm

Nanometer-sized ZnO crystals with the diameter from 20 nm to 110 nm were prepared by homogenous precipitation method (HPM). The photoluminescence (PL) spectra of as-prepared nanoparticles under excitation at the wavelength of 320 nm were detected. The PL spectra were fitted with Gaussian curves, in which a good fitting consisting of six Gaussian peaks was obtained. We observed that the multi-peak centers do not change much, while the relative amplitude of Gaussian combination to the band-to-band emission decreases rapidly with the increased grain size. It shows that the broadband emission at the lower energy is associated with the surface states.

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Structure and Hardness of Cryorolled and Heat-Treated 2xxx Aluminum Alloy

Materials Science Forum ◽

10.4028/www.scientific.net/msf.667-669.925 ◽

2010 ◽

Vol 667-669 ◽

pp. 925-930

Author(s):

S.V. Krymskiy ◽

Elena Avtokratova ◽

M.V. Markushev ◽

Maxim Yu. Murashkin ◽

O.S. Sitdikov

Keyword(s):

Heat Treatment ◽

Solid Solution ◽

Plastic Deformation ◽

Aluminum Alloy ◽

Severe Plastic Deformation ◽

Coarse Grained ◽

Aging Response ◽

Heat Treated ◽

Aluminum Solid Solution ◽

A Cell

The effects of severe plastic deformation (SPD) by isothermal rolling at the temperature of liquid nitrogen combined with prior- and post-SPD heat treatment, on microstructure and hardness of Al-4.4%Cu-1.4%Mg-0.7%Mn (D16) alloy were investigated. It was found no nanostructuring even after straining to 75%. Сryodeformation leads to microshear banding and processing the high-density dislocation substructures with a cell size of ~ 100-200 nm. Such a structure remains almost stable under 1 hr annealing up to 200oC and with further temperature increase initially transforms to bimodal with a small fraction of nanograins and then to uniform coarse grained one. It is found the change in the alloy post–SPD aging response leading to more active decomposition of the preliminary supersaturated aluminum solid solution, and to the alloy extra hardening under aging with shorter times and at lower temperatures compared to T6 temper.

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