Conductive Al Alloys: The Contradiction between Strength and Electrical Conductivity

Wang, Yu; Zhu, Langjie; Niu, Guodong; Mao, Jian

doi:10.1002/adem.202001249

Cited by 31 publications

(17 citation statements)

References 185 publications

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“…Such popular Al-based systems as Al-Mg-Si (6xxx series alloys) have been developed to gain additional strengthening due to precipitation of fine second phase particles [1]. Application of additional deformation and thermal treatments of Al alloys to this and other systems makes it possible to achieve an affordable trade-off between density, strength and electrical conductivity, and such alloys have found important applications as a substitution for more expensive, less widespread, and higher density Cu-based alloys [2]. Moreover, the modern approaches for microstructural design by tuning fine-scale features, especially for complex structures [3][4][5], have provided an extra-space to further enhance both the mechanical and electrical properties of Al alloys [6].…”

Section: Introductionmentioning

confidence: 99%

A Molecular Dynamics Simulation to Shed Light on the Mechanical Alloying of an Al-Zr Alloy Induced by Severe Plastic Deformation

Morkina,

Babicheva,

Korznikova

et al. 2023

Metals

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In a recent experimental work, as a result of severe plastic deformation, a non-equilibrium solid solution was obtained despite the very limited solubility of zirconium (Zr) in aluminum (Al). This opens up a new path in the development of heat-treatable alloys with improved electrical and mechanical properties, where mechanically dissolved elements can form intermetallic particles that contribute to precipitation strengthening. In the present study, molecular dynamics simulations were performed to better understand the process of mechanical dissolution of Zr within an Al model, with Zr atoms segregated along its grain boundaries. Stress–strain curves, radial distribution functions, and mechanisms of plastic deformation and dissolution of Zr in Al were analyzed. It is revealed that orientation of the grain boundary with segregation normal to the shear direction promotes more efficient mixing of alloy components compared to its parallel arrangement. This happens because in the second case, grain boundary sliding is the main deformation mechanism, and Zr tends to remain within the interfaces. In contrast, the involvement of dislocations in the case of normal orientation of grain boundaries with Zr segregation significantly contributes to deformation and facilitates better dissolution of Zr in the Al matrix. The findings obtained can provide new insights considering the role of texture during mechanical alloying of strongly dissimilar metals.

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Section: Introductionmentioning

confidence: 99%

A Molecular Dynamics Simulation to Shed Light on the Mechanical Alloying of an Al-Zr Alloy Induced by Severe Plastic Deformation

Morkina,

Babicheva,

Korznikova

et al. 2023

Metals

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“…The yield and tensile strengths of the alloy plates increase from 168 and 255 MPa to 171 and 263 MPa, respectively, and the elongation of the plates increased from 19% to a peak of 23% upon increasing the aging time at 120 °C from 1 h to 4 h. Upon increasing the aging time continuously to 192 h, the yield and tensile strengths of the alloy plates reach a maximum of 340 MPa and 382 MPa, respectively, and the corresponding elongation reduced to a minimum of 14%. The 7005 alloy plates exhibit an anomalous phenomena in that the strength and elongation simultaneously increase when the aging time is less than 4 h. This was not consistent with other research results obtained by most current scholars [ 20 , 21 ] that showed aluminum alloy elongation decreasing while its strength increased with increased aging time.…”

Section: Resultsmentioning

confidence: 61%

Effect of Precipitates on the Mechanical Performance of 7005 Aluminum Alloy Plates

Tian

Zhang

et al. 2022

Materials

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In this study, the strength, elongation, and fatigue properties of 7005 aluminum alloy plates with different configurations of precipitates were investigated by means of tensile tests, fatigue tests, and microstructural observation. We found that the number and size of GP zones in an alloy plate matrix increased and the distribution was more uniform after the aging time was extended from 1 h to 4 h at 120 °C, which led to a rise in both strength and elongation of alloy plates with the extending aging time. The fatigue life of the alloy plates shortened slightly at first, then significantly prolonged, and then shortened again with the aging time extending from 1 h to 192 h and a fatigue stress level of 185 MPa and stress ratio (R) = 0. After aging at 120 °C for 96 h, the precipitates in the alloy plate matrix were almost all metastable η′-phase particles, which had the optimal aging strengthening effect on the alloy matrix, and the degree of mismatch between the α-Al matrix and second-phase particles was the smallest; the fatigue crack initiation and propagation resistances were the largest, leading to the best fatigue performance of alloy plates, and the fatigue life of the aluminum plate was the longest, up to 1.272 ´ 106 cycles. When the aging time at 120 °C was extended to 192 h, there were a small number of equilibrium η phases in the aluminum plates that were completely incoherent with the matrix and destroyed the continuity of the aluminum matrix, easily causing stress concentration. As a result, the fatigue life of alloy plates was shortened to 9.422 ´ 105 cycles.

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“…Besides, in applications where low weight is required, there is a need for low weight conductors pushing the development of aluminium-based materials. 1) Materials with a high specific strength combined with a low electrical resistivity are of interest both for transportation industries and for power transmission lines. For example, modern cars can contain up to 5 km of wiring comprising a significant weight, so that developing advanced Al-based conductors can assist reducing the weight and cost of automobiles together with lowering environmental impact and improving fuel efficiency.…”

Section: Introductionmentioning

confidence: 99%

Potency of Severe Plastic Deformation Processes for Optimizing Combinations of Strength and Electrical Conductivity of Lightweight Al-Based Conductor Alloys

2023

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This paper presents an overview of fundamentals and potential applications of ultrafine-grained Al-based conductors developed with the help of severe plastic deformation (SPD) techniques. Based on deliberate formation of nanoscale features (such as nanoprecipitates, segregation of solutes along crystallographic defects and so on) within ultrafine grains, it is possible to optimise their mechanical and functional performance enhancing the combination of strength and electrical conductivity to produce advanced lightweight conductors required by modern industries. Guidelines related to SPD-driven development of Al alloys with properties superior to those exhibited by traditionally processed conductors are discussed.

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Conductive Al Alloys: The Contradiction between Strength and Electrical Conductivity

Cited by 31 publications

References 185 publications

A Molecular Dynamics Simulation to Shed Light on the Mechanical Alloying of an Al-Zr Alloy Induced by Severe Plastic Deformation

A Molecular Dynamics Simulation to Shed Light on the Mechanical Alloying of an Al-Zr Alloy Induced by Severe Plastic Deformation

Effect of Precipitates on the Mechanical Performance of 7005 Aluminum Alloy Plates

Potency of Severe Plastic Deformation Processes for Optimizing Combinations of Strength and Electrical Conductivity of Lightweight Al-Based Conductor Alloys

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