Structure and growth of core–shell nanoprecipitates in Al–Er–Sc–Zr–V–Si high-temperature alloys

Nasim, Wahaz; Yazdi, Sadegh; Santamarta, R.; Malik, Jahanzaib; Erdeniz, Dinc; Mansoor, Bilal; Seidman, David N.; Dunand, David C.; Караман, И.

doi:10.1007/s10853-018-2941-9

Cited by 13 publications

(4 citation statements)

References 39 publications

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“…The unique hierarchical-CNP structure resulted in an exaggerated precipitation-strengthening effect and raised the yield strength and ultimate strength to 1860 and 2500 MPa, respectively . Core–shell CNPs in Al–Zr–Sc–Er alloy systems have frequently been reported and can improve the mechanical performance of alloys at high temperatures (300–400 °C). , The addition of Er and Zr in Al–Zr–Sc–Er alloy system leads to the formation of spheroidal Al 3 (Sc, Zr, Er) CNPs with a core/double-shell structure comprising an Er-enriched core surrounded by an Sc-enriched inner shell and a Zr-enriched outer shell (Figure c). The core–shell structure is shown to be stable and difficult to coarsen even at a high temperature of 400 °C for 64 days.…”

Section: Nanoprecipitationmentioning

confidence: 99%

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Phase Engineering of Nanostructural Metallic Materials: Classification, Structures, and Applications

Gu,

Duan,

Liu

et al. 2024

Chem. Rev.

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Metallic materials are usually composed of single phase or multiple phases, which refers to homogeneous regions with distinct types of the atom arrangement. The recent studies on nanostructured metallic materials provide a variety of promising approaches to engineer the phases at the nanoscale. Tailoring phase size, phase distribution, and introducing new structures via phase transformation contribute to the precise modification in deformation behaviors and electronic structures of nanostructural metallic materials. Therefore, phase engineering of nanostructured metallic materials is expected to pave an innovative way to develop materials with advanced mechanical and functional properties. In this review, we present a comprehensive overview of the engineering of heterogeneous nanophases and the fundamental understanding of nanophase formation for nanostructured metallic materials, including supra-nano-dual-phase materials, nanoprecipitation-and nanotwin-strengthened materials. We first review the thermodynamics and kinetics principles for the formation of the supra-nano-dual-phase structure, followed by a discussion on the deformation mechanism for structural metallic materials as well as the optimization in the electronic structure for electrocatalysis. Then, we demonstrate the origin, classification, and mechanical and functional properties of the metallic materials with the structural characteristics of dense nanoprecipitations or nanotwins. Finally, we summarize some potential research challenges in this field and provide a short perspective on the scientific implications of phase engineering for the design of next-generation advanced metallic materials.

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Section: Nanoprecipitationmentioning

confidence: 99%

Section: Nanoprecipitationmentioning

confidence: 99%

Phase Engineering of Nanostructural Metallic Materials: Classification, Structures, and Applications

Gu,

Duan,

Liu

et al. 2024

Chem. Rev.

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“…Few reports emphasised a two-step ageing process in Al-Cu-Sc based alloys modified with Zr, V, and Ti. It results in forming coarsening resistant Al 3 Sc precipitates by allowing the segregation of low diffusing transition elements (Zr, V or Ti) at the Al 3 Sc precipitate/matrix interface during ageing at higher temperatures [39][40][41]. The addition of Zr to Al-Cu-Sc alloys was reported to enhance the high-temperature performance of the alloys [42][43][44][45].…”

Section: Strengthening Due To Ordered Precipitatesmentioning

confidence: 99%

Newer Developments in Aluminium Alloys Through Ordered Precipitates and Segregation of Transition Elements

Bansal

Chattopadhyay

2022

Trans Indian Inst Met

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Since its discovery, aluminium alloys have played a significant role in several sectors of industrial developments. The combination of high strength and low density has made these alloys attractive and played a crucial role in the automotive and aerospace industry. However, newer developments have brought exciting possibilities in high temperature and high-temperature alloy developments in the last few years. One of them is the addition of coherent, ordered precipitates of nanometric sizes. These precipitates also promote hierarchical structures and resistance to microstructure coarsening. It is also increasingly realised that controlled segregation at the precipitate/matrix interface can control and improve room and high-temperature properties. This article focuses on these developments that are expected to open up new possibilities and applications in the automotive and energy sectors.

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“…Simultaneous addition of titanium, zirconium and hafnium is also used to ensure the effective use of scandium as a modifier of aluminum alloys. This technique provides the formation of thermally stable phases of Al 3 (Sc,Zr/Ti/Hf), including -with a two-layer "coreshell" structure with a favorable structure of the L1 2 -type [39][40][41].…”

Section: різнеmentioning

confidence: 99%

Microalloying and Modification of Cast Aluminum Alloys for Increasing their Level of Exploitation Properties at Elevated Temperatures. A Review

Voron¹,

Pruss²,

Byba³

2021

Processy litʹâ

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The work is devoted to the analysis of the most effective microalloying additives and modifiers influence on increasing the mechanical properties of Al-Si-based alloys (silumins) during their operation at elevated temperatures. It is shown that cast aluminum alloys based on the Al-Si system belong to a number of cheap and widely used heat-resistant aluminum alloys, but their level of mechanical properties is quite low, and operating temperature limits are mostly determined by 250 °C. Modification and microalloying is widely used to increase the level of operational properties of this type of alloys. In recent years, complex multicomponent modification of silumins by such elements as chromium, manganese, nickel, cobalt, titanium, zirconium and vanadium is considered to be more and more effective in strengthening, grain refinement, shape shifting of iron-containing phases, etc. Triple addition of these elements in a total amount up to 0.25 wt. % in many cases increases the efficiency of modification, compared with the addition of a single element. It is shown, that the addition of vanadium, molybdenum and tungsten helps to increase the hardness of alloys in the cast state. In this case, after hardening and two-stage aging, for alloys with molybdenum there is an increase in yield strength by 10% while maintaining the level of strength. Hafnium is considered as a promising nucleating element, the addition of which also significantly increases the resistance of recrystallization. Its addition to heat-resistant aluminum alloys can provide stabilization of mechanical properties up to 400 0 C. It is necessary to ensure the maximum possible grinding of hafnium intermetallics, especially in the presence of silicon in the alloy. Modification of aluminum alloys with scandium with the addition of titanium, zirconium or hafnium promotes the formation of Al 3 (Sc,Zr/Ti/Hf) dispersoids with a cubic crystal lattice of favorable symmetry L1 2 and a stable layered «core-shell» structure. The content of silicon in the alloy should be minimal due to the formation of harmful silicides. The addition of rare earth metals has a similar effect, but without the formation of layered structures. In this case, REM can form silicides, and can modify eutectic or primary silicon. In both cases, the addition of transition metals or REM, simultaneously with the modification of scandium alloys, increases the high-temperature stability of cast Al-Si-based aluminum alloys mechanical properties of through the formation of less active and diffusion-moving reinforcing dispersed phases.

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Structure and growth of core–shell nanoprecipitates in Al–Er–Sc–Zr–V–Si high-temperature alloys

Cited by 13 publications

References 39 publications

Phase Engineering of Nanostructural Metallic Materials: Classification, Structures, and Applications

Phase Engineering of Nanostructural Metallic Materials: Classification, Structures, and Applications

Newer Developments in Aluminium Alloys Through Ordered Precipitates and Segregation of Transition Elements

Microalloying and Modification of Cast Aluminum Alloys for Increasing their Level of Exploitation Properties at Elevated Temperatures. A Review

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