There is, I think, something ethereal about i —the square root of minus one. I remember first hearing about it at school. It seemed an odd beast at that time—an intruder hovering on the edge of reality.

Usually familiarity dulls this sense of the bizarre, but in the case of i it was the reverse: over the years the sense of its surreal nature intensified. It seemed that it was impossible to write mathematics that described the real world in …

I and i

In recent years, much progress has been made in the studies of nanostructured Al alloys for advanced structural and functional use associated both with the development of novel routes for the fabrication of bulk nanostructured materials using severe plastic deformation (SPD) techniques and with investigation of fundamental mechanisms leading to improved properties. This review paper discusses new concepts and principles in application of SPD processing to fabricate bulk nanostructured Al alloys with advanced properties. Special emphasis is placed on the relationship between microstructural features, mechanical, chemical, and physical properties, as well as the innovation potential of the SPD-produced nanostructured Al alloys.

Nanostructured aluminium alloys produced by severe plastic deformation: New horizons in development

http://plast.me.tut.ac.jp/present/joining_CIRP.pdf

Joining by plastic deformation

The transformation-induced plasticity (TRIP) in advanced high-strength steels (AHSS) is reviewed, where the main concepts and the recent progress in the processing and properties of AHSS are introduced. The metastable austenitic stainless and multiphase TRIP-assisted steels, as well as the more recent third generation AHSS grades, namely the medium-Mn and quenching and partitioning (Q&P) steels, are critically discussed. These steels utilize the TRIP effect and the enhanced work-hardening rate through the transformation of (retained) austenite in their microstructures to martensite during plastic deformation for the improvement of strength-ductility balance, which make them especially suitable for the automotive industry to be used in the lightweight car body for addressing the safety, fuel consumption, and air pollution issues. The kinetics of strain-induced martensitic transformation (SIMT) as well as the effects of chemical composition, grain size, deformation temperature, strain rate, and deformation mode on the austenite stability are reviewed. The effects of holding temperature and time during the isothermal bainitic transformation (IBT) in TRIP-aided steels, during the austenite-reverted-transformation (ART) annealing in medium-Mn steels, and during the quenching and partitioning steps in the Q&P steels are critically discussed towards enhancement of the amount of retained austenite and optimization of strength-ductility trade off. The alternative thermomechanical processing routes as well as the modified grades such as δ-TRIP and quenching-partitioning-tempering steels are also introduced.

Transformation-induced plasticity (TRIP) in advanced steels: A review

Thermomechanical processing of advanced high strength steels

In this study, accumulative roll bonding (ARB) process was carried out on an AA1100 aluminum sheet up to 10 cycles. Electron backscattering diffraction (EBSD) method was utilized to investigate the microstructural evolution during the ARB process. It was observed that the ARB is a promising process for fabricating ultra-fine grained structures in aluminum sheets. The results indicate that several mechanisms are responsible for the microstructural changes at different levels of strain during this process. Grain subdivision as well as the development of sub-grains are the major mechanisms at the early stages of ARB. Strain induced transition of low angle to high angle grain boundaries and the formation of thin lamellar structure occurs at the medium levels of strain. Finally, the progressive break up of this thin lamellar structure into more equiaxed grains is the dominant mechanism at relatively high strains. By reducing the grain size, the yield stress and the tensile strength of the ARBed sheets increased significantly and reached the maximum values of 282 and 333 MPa after the tenth cycle. The strength held Hall–Petch relationship and was in a good conformity with the microstructural changes.

Microstructure evolution and mechanical properties of AA1100 aluminum sheet processed by accumulative roll bonding

Experimental study and FEM analysis of redundant strains in flow forming of tubes

A novel SPD process for manufacturing of high strength tubes and cylinders by accumulative spin-bonding (ASB) is proposed. It is demonstrated that due to incremental deformation in this process, high strain rate without considerable temperature rise is achieved. This is accompanied with a high value of Zener–Hollomon parameter as a characteristic of this SPD process. ASB was applied to a commercially pure aluminum up to four cycles and its effects on the microstructure and mechanical properties were examined by optical microscopy, TEM, EBSD, microhardness and tension tests. The results show that ultra-fine grains are developed during the process by formation of subgrains at early stages followed by increase of the misorientations at later stages. This leads to a nanostructure with average grain thickness and length of 186 and 419 nm, respectively. It is indicated that while the hardness of outer regions is more than the inner ones, the hardness and its homogeneity is increased with the ASB cycles. Periodical presence of external layers within the thickness and consequent hardness saturation are responsible for this hardness evolution. As a result of grain refinement and the scheme of hardness development, the yield and tensile strength of material are significantly increased. Moreover, the ratio of the yield strength to the tensile strength and consequently the uniform elongation is decreased with the ASB cycles.

Accumulative spin-bonding (ASB) as a novel SPD process for fabrication of nanostructured tubes

Recently accumulative roll bonding has been used as a novel method to produce particle reinforced metal matrix composites. In this study, aluminum matrix composite reinforced by submicron particulate alumina was successfully produced and the effects of number of ARB cycles and the amount of alumina content on the microstructure and mechanical properties of composites were investigated. According to the results of tensile tests, it is shown that the yield and tensile strengths of the composite are increased with the number of ARB cycles. Scanning electron microscopy (SEM) reveals that particles have a random and uniform distribution in the matrix by the ARB cycles and a strong mechanical bonding takes place at the interface of particle-matrix. It is also found that the tensile strength of the composite, as a function of alumina content, has a maximum value at 2 vol.%, which is 5.1 times higher than that of the annealed aluminum.

Abbas Akbarzadeh

Papers

Microstructure evolution and mechanical properties of AA1100 aluminum sheet processed by accumulative roll bonding

Experimental study and FEM analysis of redundant strains in flow forming of tubes

Accumulative spin-bonding (ASB) as a novel SPD process for fabrication of nanostructured tubes

Production of high strength Al–Al2O3 composite by accumulative roll bonding

Effect of cooling rate on the microstructure and mechanical properties of microalloyed forging steel