Sandwich structure helps ceramic retain properties at atomic scales

Atomic-scale structure of the LSCO-LSMO sandwich obtained by high-resolution electron microscopy. Image: NC State.
Atomic-scale structure of the LSCO-LSMO sandwich obtained by high-resolution electron microscopy. Image: NC State.

Researchers at North Carolina (NC) State University have found that the oxide ceramic material lanthanum strontium manganite (LSMO) retains its magnetic properties in atomically thin layers if it is ‘sandwiched’ between two layers of a different ceramic oxide, lanthanum strontium chromium oxide (LSCO). These findings have implications for the future use of LSMO in spintronic-based computing and storage devices.

In its bulk form, LSMO has both magnetic and metallic properties. The conductivity of the material can be altered by changing its magnetic field, which makes LSMO appealing for use as a switch in spintronic devices. However, when the material gets to a certain thinness – between five and 10 atomic layers – it loses these properties.

Divine Kumah, assistant professor of physics at NC State and corresponding author of a paper on this work in npj Quantum Materials, wanted to know why LSMO loses its magnetic properties at a particular thinness, and to find a way to make LSMO magnetic in thin form.

Together with colleagues and graduate students from NC State, Kumah first grew thin films of LSMO on strontium titanate – a non-magnetic substrate commonly used as a neutral scaffold. The team grew films ranging from two to 10 atomic layers thick and tested them for magnetic properties.

Next, the team utilized the synchrotron light source at Argonne National Laboratory to obtain a three-dimensional view of the arrangement of the atoms within the thin layers of LSMO. They found that at extreme thinness, the oxygen and manganese atoms moved slightly out of alignment on the surface of the material, effectively switching off its magnetism.

"At about five atomic layers, we saw distortions on the surface of the layer and at the bottom interface with the scaffold," Kumah says. "The oxygen and manganese atoms rearrange themselves. Magnetism and electrical conductivity in LSMO are related to how these two atoms bond, so if there are polar distortions in the film where they move up and down, the bonds stretch out, electrons can't move through the material effectively and magnetism is switched off."

The team noted that these distortions started at the top of the film and extended approximately three layers below the surface.

"We found that the distortions occur because the crystal structure creates an electric field at the surface," Kumah says. "The oxygen and manganese atoms move in order to cancel the electric field. Our challenge was to grow something at the interfaces that is compatible with LSMO structurally but that is also insulating, so that we remove the electric field, stop the movement of the oxygen and manganese atoms and retain magnetic properties."

The researchers found that by using two layers of LSCO on either side of the LSMO, the LSMO could retain its magnetic properties at two atomic layers.

"It is like a sandwich – LSCO is the bread and LSMO is the meat," Kumah says. "You can use fewer than five layers of LSMO in this arrangement without any atomic displacement. Hopefully our work has shown that these materials can be thin enough to be useful in spintronics devices."

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