Mechanical strain can cause electronic pain in metals

“The atomic lattice of a metal and its mechanical properties are generally thought of as being unaffected by which electronic states are occupied and which are empty, but in this work, we show that this is not always a good assumption.”Clifford Hicks, University of Birmingham

New research from the University of Birmingham in the UK shows that the electronic structure of metals can strongly affect their mechanical properties.

The research, reported in a paper in Science, demonstrates experimentally, for the first time, that the electronic and mechanical properties of a metal are connected. Scientists knew there would be a connection in theory but thought that it would be too small to detect in an experiment.

“Mechanical properties are typically described in terms of the bonding between atoms, while electronic properties of metals are described by states that extend across many atoms,” explained Clifford Hicks, a reader in condensed matter physics, who worked on the study. “The atomic lattice (the term used to describe the arrangement of atoms) of a metal and its mechanical properties are generally thought of as being unaffected by which electronic states are occupied and which are empty, but in this work, we show that this is not always a good assumption.”

The researchers from the University of Birmingham and the Max Planck Institute for Chemical Physics of Solids in Dresden, Germany, conducted experiments on the superconducting metal strontium ruthenate (Sr₂RuO₄). By measuring lattice distortion as a function of applied stress, the team found that when Sr₂RuO₄ is compressed by about 0.5%, a measure of mechanical stiffness known as the Young's modulus decreases by about 10%, and then increases by about 20% when the material is compressed further. This change corresponds to a new set of electronic states becoming occupied, at a transition that had been identified earlier through electronic but not mechanical measurements.

“Whilst it is completely standard to measure stress-strain relationships in mechanical engineering, it is not something that has been done to study electronic properties,” said Hicks. “This is because the metals that have interesting electronic properties tend to be brittle, making it hard to apply large forces. Also, large strains are typically required to meaningfully alter electronic properties. In this experiment, samples of Sr₂RuO₄ were compressed by up to 1%. To visualize that, imagine taking a meterstick made of granite, and squeezing it until it is 99cm long.”

To overcome these hurdles, the scientists had to build new instrumentation that could measure small and delicate samples and handle cryogenic temperatures, as electronic measurements are more accurate at lower temperatures. This took five years of planning and design.

Now that this experiment has been completed on one material, the scientists are keen to conduct similar measurements on other metals. A version of the machine developed for this project is manufactured by a UK-based engineering company, and as the apparatus is further developed it may find application in the study of high-strength alloys. This project provides an example of how curiosity-driven, fundamental research can lead to new technology with practical applications.

This story is adapted from material from the University of Birmingham, with editorial changes made by Materials Today. The views expressed in this article do not necessarily represent those of Elsevier. Link to original source.