A Study Provides New Insights Into van der Waals Materials

Newswise — Van der Waals materials that are layered on top of each other are of high interest for electronic and photonic applications. A recent study by Penn State and SLAC National Accelerator Laboratory, in California, provides new insights into the interactions of layered materials with laser and electron beams.

The study utilizes a combination of ultrafast pulses of laser light that excite the atoms of a material lattice, in this case gallium telluride, followed by an ultrafast pulse of an electron beam, which shows the lattice vibrations in real time using electron diffraction. This new ability could lead to better understanding of materials.

“This is a quite unique technique,” said Shengxi Huang, assistant professor of electrical engineering and corresponding author of a paper in ACS Nano that describes their work. “The purpose is to understand fully the lattice vibrations, including in-plane and out-of-plane.”

One of the interesting observations in their work is the breaking of a law that applies to all material systems. Friedel’s Law posits that in the diffraction pattern, the pairs of centrosymmetric Bragg peaks should be symmetric, directly resulting from Fourier transformation. In this case, however, the pairs of Bragg peaks show opposite oscillating patterns. They call this phenomenon the dynamic breaking of Friedel’s Law. It is a very rare if not unprecedented observation in the interactions between the beams and these materials.

“Why do we see the breaking of Fiedel’s Law? It is because of the lattice structure of this material,” she said. “In layered 2D materials, the atoms in each layer typically align very well in the vertical direction. In gallium telluride, the atomic alignment is a little bit off.”

When the laser beam shines onto the material, the heating generates the lowest-order longitudinal acoustic phonon mode, which creates a wobbling effect for the lattice. This can affect the way electrons diffract in the lattice, leading to the unique dynamic breaking of Friedel’s law.

This technique is also useful for studying phase change materials, which absorb or radiate heat during phase change. Such materials are used to generate the electrocaloric effect in solid-state refrigerators. This technique will also be interesting to people who study oddly structured crystals and the general 2D materials community.  

The lead author on the article, titled “Coherent Lattice Wobbling and Out-of-Phase Intensity Oscillations of Friedel Pairs Observed by Ultrafast Electron Diffraction” is Huang’s postdoctoral scholar Qingkai Qian. Additional Penn State authors in her group are graduate students Kunyan Zhang and Lanxin Jia, and research scholar Yu Zhou. Xijie Wang led the ten-member SLAC team.

Support for this work was provided by the National Science Foundation. The SLAC is supported by the Department of Energy.