A new ultrasound technique that measures the strength of atomic bonds within two-dimensional (2D) materials, as well as the weaker forces between layers, has shown that the velocity of sound within these materials depends on the layers’ stacking arrangement. The technique, which was developed by researchers in the UK, could be used to craft “designer” 2D compounds by stacking layers in different ways while monitoring their bonding forces and studying how these relate to the materials’ physical and chemical properties.

2D materials such as graphene and metal chalcogenides are made up of stacked layers, or sheets, just one atom thick. While the sheets are bonded to each other only weakly, via van der Waals (vdW) forces, the atoms within each sheet form extremely strong covalent/ionic bonds. These dramatically different bonding strengths make it possible to exfoliate, or peel off, perfect single layers of these materials from bulk samples. Indeed, this was how graphene was first isolated from bulk graphite in 2004.

Techniques that can measure the strength of these atomic bonds and vdW forces in a non-destructive way are, however, lacking. This restricts scientists’ ability to explore various unusual phenomena (such as capillary condensation, the quantum anomalous Hall effect and even room-temperature superconductivity in monolayer sheets) that make 2D materials so promising for next-generation electronics. What is more, previous measurement efforts have produced conflicting results.

Technique similar to medical ultrasound

Researchers at the University of Nottingham and Loughborough University have now developed a technique that uses fast laser pulses to generate and detect tiny, transient strains in the crystalline lattice of indium selenide (In₂Se₃). This unique approach, backed by theoretical analyses by Alexander Balanov and Mark Greenaway at Loughborough, makes it possible to measure both the strong covalent bonds and weak vdW forces in the different phases of In₂Se₃ without damaging the material, says team member Wenjing Yan, a physicist at Nottingham.

Yan goes on to explain that the technique works in a similar way to medical ultrasound, but at a much higher, sub-terahertz, frequency. It involves sending a “pump” laser pulse just 120 femtoseconds long into flakes of In₂Se₃ to generate coherent phonons (quantized sound waves) that then travel through the material, interacting with its atomic bonds. The properties of these phonons reveal information about the strength of the atomic bonds, and they are measured by a second “probe” laser pulse with picosecond time resolution.

The technique is non-invasive because the laser pulses merely deform the crystal slightly, rather than destroying it. Indeed, the system may be considered as a sequence of springs: by knowing the speed of sound from measurements and how these springs respond to the deformation, the researchers can extract the relative strength of the covalent forces between the atoms and the vdW forces between the layers. “If we apply so-called density function theory with the help of high-performance computers, we can numerically estimate these forces for different stacking configurations and suggest how to tune the elastic, electric and even chemical properties of different polymorphs of vdW materials,” Greenaway explains.

Different phases, different properties

The researchers chose to study In₂Se₃ because it has a range of technological applications, including solar cells, photodiodes, ferroelectric field-effect transistors, and non-volatile memory elements. It also exists in several phases, denoted α, β, β′, γ and δ, each with a different crystalline structure.

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Making images with sound

The α- and β-In₂Se₃ phases are particularly interesting for materials designers. The α-phase is ferroelectric, with different ferroelectric properties for its hexagonal (2H) and rhombohedral (3R) arrangements in which the individual (quintuple) layers are stacked in an AB and ABC arrangement, respectively. In contrast, β-In₂Se₃(3R), which forms when α-In₂Se₃ is annealed, is not ferroelectric, and behaves as a superconductor at high pressures.

The researchers, who report their work in Advanced Functional Materials, found that sound waves travel at very different speeds in these different phases. Yan compares the team’s findings to the differences between pancakes and Yorkshire pudding. “Both foods are made from the same mixture: egg, flour and milk, but their different cooking processes give them different structures and properties,” she explains. “Although this is obvious in the macroscopic world, finding such differences in nanostructured materials due to subtle differences in vdW forces is surprising and exciting.”