Effect of Magnesium and Silicon on Temperature and Mechanical Properties in Refill Friction Stir Spot Welding of Aluminum to Titanium

Lasse Malaske; Uceu F.H. Suhuddin; Benjamin Klusemann

doi:10.4028/p-GJ7osM

Paper Titles

Effect of Magnesium and Silicon on Temperature and Mechanical Properties in Refill Friction Stir Spot Welding of Aluminum to Titanium
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Welding Distortion Control in T-Joint Structure of Al-Sheets by Using Pre-Tension
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Microstructural Characterisations of Static Strain Ageing in C-Mn Steel Welds of the Secondary Circuit of Pressurized Water Reactors
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Creep Properties of P92 Pipe Weld after Annealing at 600 and 650°C
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Application of Electron Beam Welding in the Production of TEMPALOY AA1 and T92 Butt Joints of Pipes Assigned for the Energy Industry
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Evolution of Inclusions in Physically Simulated Heat-Affected Zones of a Weld Metal Used with a 500 MPa Offshore Steel
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Effect of Thermal Cycle Profile on Thermal Fatigue Life of Sn-3.0Ag-0.5Cu Solder Joints for Wafer-Level Chip Scale Package
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HomeKey Engineering MaterialsKey Engineering Materials Vol. 1040Effect of Magnesium and Silicon on Temperature and...

Effect of Magnesium and Silicon on Temperature and Mechanical Properties in Refill Friction Stir Spot Welding of Aluminum to Titanium

Abstract:

Optimizing the mechanical properties of aluminum to titanium welds is crucial to establish applications for dissimilar lightweight structures in the aerospace industry. In this context, solid-state welding technologies have proven effective in terms of short joining cycles, allowing the combination of cost-effective production and structural weight optimization. However, metallurgical effects between aluminum and titanium in the joint interface are still not completely understood due to differences in physical as well as chemical characteristics. In this study, aluminum alloy 6013 was welded to Ti6Al4V by refill Friction Stir Spot Wel ding, including systematic variations of Mg and Si alloying element content in the used AA6013 sheets. In total five different Al alloys were welded to the titanium to investigate the influence of Mg and Si during processing. Apart from the material selection, the weld strength is mainly influenced by the intermetallic compound thickness at the interface, which in turn primarily depends on the exposed temperature cycle. Consequently, major interest during this study was given on the temperature evolution, interfacial features and the global mechanical properties.

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Key Engineering Materials (Volume 1040)

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1-8

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https://doi.org/10.4028/p-GJ7osM

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January 2026

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Lasse Malaske*, Uceu F.H. Suhuddin, Benjamin Klusemann

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