AI Article Synopsis
- High-strength aluminum alloys are typically limited to low temperatures (below ~150 °C), but there’s a need for alloys that can perform in the 300‒400 °C range for lightweight design and energy applications.* -
- Research demonstrates a new strategy using interstitial solutes in Sc-added Al-Cu-Mg-Ag alloys to create stable nanoprecipitates (V phase) that significantly improve creep resistance and tensile strength at higher temperatures (~100 MPa at 400 °C).* -
- The formation of these stable V phase nanoprecipitates is facilitated by a unique phase transformation process that helps to harmonize the interactions between slow-diffusing and fast-diffusing atoms, suggesting potential for large
Article Abstract
Lightweight design strategies and advanced energy applications call for high-strength Al alloys that can serve in the 300‒400 °C temperature range. However, the present commercial high-strength Al alloys are limited to low-temperature applications of less than ~150 °C, because it is challenging to achieve coherent nanoprecipitates with both high thermal stability (preferentially associated with slow-diffusing solutes) and large volume fraction (mostly derived from high-solubility and fast-diffusing solutes). Here we demonstrate an interstitial solute stabilizing strategy to produce high-density, highly stable coherent nanoprecipitates (termed the V phase) in Sc-added Al-Cu-Mg-Ag alloys, enabling the Al alloys to reach an unprecedented creep resistance as well as exceptional tensile strength (~100 MPa) at 400 °C. The formation of the V phase, assembling slow-diffusing Sc and fast-diffusing Cu atoms, is triggered by coherent ledge-aided in situ phase transformation, with diffusion-dominated Sc uptake and self-organization into the interstitial ordering of early-precipitated Ω phase. We envisage that the ledge-mediated interaction between slow- and fast-diffusing atoms may pave the way for the stabilization of coherent nanoprecipitates towards advanced 400 °C-level light alloys, which could be readily adapted to large-scale industrial production.
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| http://dx.doi.org/10.1038/s41563-022-01420-0 | DOI Listing |
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