Nanotechnology Now – Press Release: Researchers find a better way to design metal alloys: System uses machine learning to analyze boundaries between crystal grains, allowing for selection of desired properties in a new metal

Home > Press > Researchers find a better way to design metal alloys: System uses machine learning to analyze boundaries between crystal grains, allowing for selection of desired properties in a new metal

Researchers have found a new way to predict the properties of metal alloys based on reactions at the boundaries between the crystalline grains of the primary metal. In this image, the colored dots indicate the likelihood that atoms will collect along these boundaries rather than penetrating through. Credits:Image courtesy of the researchers

Abstract:
Advanced metal alloys are essential in key parts of modern life, from cars to satellites, from construction materials to electronics. But creating new alloys for specific uses, with optimized strength, hardness, corrosion resistance, conductivity, and so on, has been limited by researchers’ fuzzy understanding of what happens at the boundaries between the tiny crystalline grains that make up most metals.

Researchers find a better way to design metal alloys: System uses machine learning to analyze boundaries between crystal grains, allowing for selection of desired properties in a new metal

Cambridge, MA | Posted on December 11th, 2020

When two metals are mixed together, the atoms of the secondary metal might collect along these grain boundaries, or they might spread out through the lattice of atoms within the grains. The material’s overall properties are determined largely by the behavior of these atoms, but until now there has been no systematic way to predict what they will do.

Researchers at MIT have now found a way, using a combination of computer simulations and a machine-learning process, to produce the kinds of detailed predictions of these properties that could guide the development of new alloys for a wide variety of applications. The findings are described today in the journal Nature Communications, in a paper by graduate student Malik Wagih, postdoc Peter Larsen, and professor of materials science and engineering Christopher Schuh.

Schuh explains that understanding the atomic-level behavior of polycrystalline metals, which account for the vast majority of metals we use, is a daunting challenge. Whereas the atoms in a single crystal are arranged in an orderly pattern, so that the relationship between adjacent atoms is simple and predictable, that’s not the case with the multiple tiny crystals in most metal objects. “You have crystals smashed together at what we call grain boundaries. And in a conventional structural material, there are millions and millions of such boundaries,” he says.

These boundaries help to determine the material’s properties. “You can think of them as the glue holding the crystals together,” he says. “But they are disordered, the atoms are jumbled up. They don’t match either of the crystals they’re joining.” That means they offer billions of possible atomic arrangements, he says, compared to just a few in a crystal. Creating new alloys involves “trying to design those regions inside a metal, and it’s literally billions of times more complicated than designing in a crystal.”

Schuh draws an analogy to people in a neighborhood. “It’s kind of like being in a suburb, where you may have 12 neighbors around you. In most metals, you look around, you see 12 people and they’re all at the same distance away from you. It’s totally homogenous. Whereas in a grain boundary, you still have something like 12 neighbors, but they’re all at different distances and they’re all different-size houses in different directions.”

Traditionally, he says, those designing new alloys simply skip over the problem, or just look at the average properties of the grain boundaries as though they were all the same, even though they know that’s not the case.

Instead, the team decided to approach the problem rigorously by examining the actual distribution of configurations and interactions for a large number of representative cases, and then using a machine-learning algorithm to extrapolate from these specific cases and provide predicted values for a whole range of possible alloy variations.

In some cases, the clustering of atoms along the grain boundaries is a desired property that can enhance a metal’s hardness and resistance to corrosion, but it can also sometimes lead to embrittlement. Depending on the intended use of an alloy, engineers will try to optimize the combination of properties. For this study, the team examined over 200 different combinations of a base metal and an alloying metal, based on combinations that had been described on a basic level in the literature. The researchers then systematically simulated some of these compounds to study their grain boundary configurations. These were used to generate predictions using machine learning, which were in turn validated with more focused simulations. The machine-learning predictions closely matched the detailed measurements.

As a result, the researchers were able to show that many alloy combinations that had been ruled out as unviable in fact turn out to be feasible, Wagih says. The new database compiled from this study, which has been made available in the public domain, could help anyone now working on designing new alloys, he says.

The team is forging ahead with the analysis. “In our ideal world, what we would do is take every metal in the periodic table, and then we would add every other element in the periodic table to it,” Schuh says. “So you take the periodic table and you cross it with itself, and you would check every possible combination.” For most of those combinations, basic data are not yet available, but as more and more simulations are done and data collected, this can be integrated into the new system, he says.

The work was supported by the U.S. Department of Energy, Office of Basic Energy Sciences.

###

Written by David L. Chandler, MIT News Office

####

For more information, please click here

Contacts:
Abby Abazorius, MIT News Office
617.253.2709

Copyright © Massachusetts Institute of Technology

If you have a comment, please Contact us.

Issuers of news releases, not 7th Wave, Inc. or Nanotechnology Now, are solely responsible for the accuracy of the content.

Bookmark:

Paper: “Learning grain boundary segregation energy spectra in polycrystals.”

News and information

Stevens creates entangled photons 100 times more efficiently than previously possible: Ultra-bright photon source brings scalable quantum photonics within reach December 17th, 2020

CEA-Leti Papers at IEDM 2020 Highlight Progress in Overcoming Challenges to Making GaN Energy-Saving, Power-Electronics Devices: Gallium Nitride Seen as Highly Efficient Replacement for Silicon In Wide Range of Consumer and Industrial Uses December 17th, 2020

Weak force has strong impact on nanosheets: Rice lab finds van der Waals force can deform nanoscale silver for optics, catalytic use December 15th, 2020

Aledia, French Developer of Next-Generation MicroLED Displays For High-Volume Consumer Markets, Announces it Has Produced its First Nanowire Chips on 300mm Silicon Wafers Using CEA-Leti Pilot Lines: Company will produce microLEDs on both 200mm and 300mm silicon wafers December 15th, 2020

Govt.-Legislation/Regulation/Funding/Policy

Weak force has strong impact on nanosheets: Rice lab finds van der Waals force can deform nanoscale silver for optics, catalytic use December 15th, 2020

Nanomaterials researchers in Finland, the United States and China have created a color atlas for 466 unique varieties of single-walled carbon nanotubes. December 14th, 2020

Faraday fabrics? MXene-coated fabric could contain electronic interference in wearable devices December 11th, 2020

Stretchable micro-supercapacitors to self-power wearable devices December 11th, 2020

Possible Futures

Stevens creates entangled photons 100 times more efficiently than previously possible: Ultra-bright photon source brings scalable quantum photonics within reach December 17th, 2020

CEA-Leti Papers at IEDM 2020 Highlight Progress in Overcoming Challenges to Making GaN Energy-Saving, Power-Electronics Devices: Gallium Nitride Seen as Highly Efficient Replacement for Silicon In Wide Range of Consumer and Industrial Uses December 17th, 2020

Weak force has strong impact on nanosheets: Rice lab finds van der Waals force can deform nanoscale silver for optics, catalytic use December 15th, 2020

Aledia, French Developer of Next-Generation MicroLED Displays For High-Volume Consumer Markets, Announces it Has Produced its First Nanowire Chips on 300mm Silicon Wafers Using CEA-Leti Pilot Lines: Company will produce microLEDs on both 200mm and 300mm silicon wafers December 15th, 2020

Discoveries

Stevens creates entangled photons 100 times more efficiently than previously possible: Ultra-bright photon source brings scalable quantum photonics within reach December 17th, 2020

Weak force has strong impact on nanosheets: Rice lab finds van der Waals force can deform nanoscale silver for optics, catalytic use December 15th, 2020

Nanomaterials researchers in Finland, the United States and China have created a color atlas for 466 unique varieties of single-walled carbon nanotubes. December 14th, 2020

An LED that can be integrated directly into computer chips: The advance could cut production costs and reduce the size of microelectronics for sensing and communication December 14th, 2020

Materials/Metamaterials

Weak force has strong impact on nanosheets: Rice lab finds van der Waals force can deform nanoscale silver for optics, catalytic use December 15th, 2020

RUDN University physicists described a new type of amorphous solid bodies December 4th, 2020

Quantum nanodiamonds may help detect disease earlier: The quantum sensing abilities of nanodiamonds can be used to improve the sensitivity of paper-based diagnostic tests, potentially allowing for earlier detection of diseases such as HIV, according to a study led by UCL research November 27th, 2020

One-way street for electrons: Scientists observe directed energy transport between neighbouring molecules in a nanomaterial November 27th, 2020

Announcements

Stevens creates entangled photons 100 times more efficiently than previously possible: Ultra-bright photon source brings scalable quantum photonics within reach December 17th, 2020

CEA-Leti Papers at IEDM 2020 Highlight Progress in Overcoming Challenges to Making GaN Energy-Saving, Power-Electronics Devices: Gallium Nitride Seen as Highly Efficient Replacement for Silicon In Wide Range of Consumer and Industrial Uses December 17th, 2020

Weak force has strong impact on nanosheets: Rice lab finds van der Waals force can deform nanoscale silver for optics, catalytic use December 15th, 2020

Aledia, French Developer of Next-Generation MicroLED Displays For High-Volume Consumer Markets, Announces it Has Produced its First Nanowire Chips on 300mm Silicon Wafers Using CEA-Leti Pilot Lines: Company will produce microLEDs on both 200mm and 300mm silicon wafers December 15th, 2020

Interviews/Book Reviews/Essays/Reports/Podcasts/Journals/White papers/Posters

Stevens creates entangled photons 100 times more efficiently than previously possible: Ultra-bright photon source brings scalable quantum photonics within reach December 17th, 2020

CEA-Leti Papers at IEDM 2020 Highlight Progress in Overcoming Challenges to Making GaN Energy-Saving, Power-Electronics Devices: Gallium Nitride Seen as Highly Efficient Replacement for Silicon In Wide Range of Consumer and Industrial Uses December 17th, 2020

Weak force has strong impact on nanosheets: Rice lab finds van der Waals force can deform nanoscale silver for optics, catalytic use December 15th, 2020

Nanomaterials researchers in Finland, the United States and China have created a color atlas for 466 unique varieties of single-walled carbon nanotubes. December 14th, 2020