Innovative high-entropy alloys, crafted through laser-based additive manufacturing, offer unprecedented strength and ductility for industrial applications. These new materials, analyzed with advanced techniques, promise enhanced performance in extreme conditions. Credit: SciTechDaily.com
Laser-based additive manufacturing produces high-entropy alloys that are stronger and less likely to fracture.
Researchers make a type of material called durable high-entropy alloys (HEAs) by combining several elemental metals. HEAs have potential uses in applications involving severe wear and tear, extreme temperatures, radiation, and high stress.
They can be made using 3D printing, also known as additive manufacturing (AM), but this usually results in poor ductility. This means 3D-printed HEAs are difficult to shape and do not deform, or stretch, enough under loads to prevent fractures.
Scientists have now used laser-based AM to form HEAs that are stronger and much more ductile. They used neutron and X-ray scattering and electron microscopy to better understand the mechanisms of these performance improvements.
Potential Industrial Applications and Energy Efficiency
Industry could one day use stronger and more easily shaped HEAs in manufacturing. To work in these applications, light and complex HEA parts need improved durability, reliability, and resistance to fracturing.
This would benefit consumers and industry, for example, by enabling the production of safer and more fuel-efficient vehicles, stronger products, and longer-lasting machinery. In addition, laser-based AM, in which lasers fuse powdered alloys into solid metal shapes, is highly energy efficient. This makes it attractive for producing new types of HEAs.
Images of the two crystal structures (right) found in a high-entropy alloy (left) made by additive manufacturing. Credit: University of Massachusetts Amherst
Nano-Lamellae Structure and Mechanical Properties
The laser-based AM process produced nanometer-thick nano-lamellae (thin layers of plates) offering high strength, while the plates’ distinct edges permit a degree of slippage (ductility). The plates consist of alternating layers of face-centered cubic (FCC) crystal structures that average approximately 150 nanometers thick and body-centered cubic (BCC) crystal structures that average approximately 65 nanometers thick.
The new HEAs exhibited high yield strengths of about 1.3 gigapascals – exceeding the strongest titanium alloys. These HEAs also offer an elongation of about 14%, which is higher than other AM metal alloys given the same yield strength. Elongation is a measure of how much bending a material can withstand without breaking.
Advanced Research Techniques and Facilities
Neutron data from the Spallation Neutron Source, a Department of Energy (DOE) Office of Science user facility at Oak Ridge National Laboratory (ORNL), enabled the researchers to examine the interior mechanical load sharing of the HEA samples while under strain.
The researchers used an SciTechDaily