# High-Throughput Study on Nanoindentation Deformation of Al-Mg-Si Alloys

**Authors:** Tong Shen, Guanglong Xu, Fuwen Chen, Shuaishuai Zhu, Yuwen Cui

PMC · DOI: 10.3390/ma18153663 · Materials · 2025-08-04

## TL;DR

This study uses a high-throughput method to explore how composition affects the deformation behavior of Al-Mg-Si alloys.

## Contribution

The study introduces an enhanced kinetic diffusion multiple method to rapidly evaluate composition-deformation relationships in Al-Mg-Si alloys.

## Key findings

- Increasing Mg and Si content suppresses the pop-in effect due to solute-dislocation interactions.
- Optimum strengthening occurs at an Mg-to-Si atomic ratio of approximately 1.
- Dislocation motion is the dominant creep mechanism in these alloys.

## Abstract

Al-Mg-Si (6XXX) series aluminum alloys are widely applied in aerospace and transportation industries. However, exploring how varying compositions affect alloy properties and deformation mechanisms is often time-consuming and labor-intensive due to the complexity of the multicomponent composition space and the diversity of processing and heat treatments. This study, inspired by the Materials Genome Initiative, employs high-throughput experimentation—specifically the kinetic diffusion multiple (KDM) method—to systematically investigate how the pop-in effect, indentation size effect (ISE), and creep behavior vary with the composition of Al-Mg-Si alloys at room temperature. To this end, a 6016/Al-3Si/Al-1.2Mg/Al KDM material was designed and fabricated. After diffusion annealing at 530 °C for 72 h, two junction areas were formed with compositional and microstructural gradients extending over more than one thousand micrometers. Subsequent solution treatment (530 °C for 30 min) and artificial aging (185 °C for 20 min) were applied to simulate industrial processing conditions. Comprehensive characterization using electron probe microanalysis (EPMA), nanoindentation with continuous stiffness measurement (CSM), and nanoindentation creep tests across these gradient regions revealed key insights. The results show that increasing Mg and Si content progressively suppresses the pop-in effect. When the alloy composition exceeds 1.0 wt.%, the pop-in events are nearly eliminated due to strong interactions between solute atoms and mobile dislocations. In addition, adjustments in the ISE enabled rapid evaluation of the strengthening contributions from Mg and Si in the microscale compositional array, demonstrating that the optimum strengthening occurs when the Mg-to-Si atomic ratio is approximately 1 under a fixed total alloy content. Furthermore, analysis of the creep stress exponent and activation volume indicated that dislocation motion is the dominant creep mechanism. Overall, this enhanced KDM method proves to be an effective conceptual tool for accelerating the study of composition–deformation relationships in Al-Mg-Si alloys.

## Linked entities

- **Chemicals:** Mg (PubChem CID 888), Si (PubChem CID 5461123)

## Full-text entities

- **Chemicals:** Al (MESH:D000535), Al-1.2Mg (-), Mg (MESH:D008274), Si (MESH:D012825)

## Full text

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## Figures

9 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12348925/full.md

## References

58 references — full list in the complete paper: https://tomesphere.com/paper/PMC12348925/full.md

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Source: https://tomesphere.com/paper/PMC12348925