Optical shear forces enable a new type of light-matter wave
Scientists from the Fritz Haber Institute of the Max Planck Society, Vanderbilt University, City University of New York, University of Nebraska, and University of Iowa have uncovered that low-symmetry crystals can support a new type of asymmetric light-matter wave enabled by optical shear forces. The results offer new possibilities for compact optical technologies to enable new ways to guide light or to store information optically.
We typically use different materials to make optical components for different functionalities such as anti-reflection coatings or lenses. In particular, crystals with asymmetric structure are very useful since here light propagates in unusual ways, enabling novel optical phenomena. Yet, not all types of crystals have been explored for photonic applications. The research team from the Fritz Haber Institute as well as renowned US research locations such as City University of New York, Vanderbilt University in Nashville, University of Nebraska and the University of Iowa explored monoclinic beta-gallium oxide. The Monoclinic crystal class has been previously unnoticed for such studies, and they uncovered that these crystals exert shear forces on light propagating along its surface.
“Using the infrared radiation of our institute’s free-electron laser, our experiments could access spectral ranges that are otherwise very challenging”, explains Alex Paarmann of the Department of Physical Chemistry of the Fritz Haber Institute. “The structure of the monoclinic crystals used in our studies looks like a distorted cuboid, where four of six sides are rectangular but two are tilted parallelograms”, Paarmann explains. “Because of this distortion, the new shear waves not only run very directed across the crystal surface but are also no longer mirror-symmetric. Thanks to the hypberbolic dependence of their wave vector on the propagation direction, we can squeeze these waves into tiny volumes. Thanks to the so-called hyperbolic dependence of their wave vector on the propagation direction, we can suqeeze these waves into tiny volumes. These so-called hyperbolic shear polaritons emerge from the coupling of infrared light to lattice vibrations called phonons in these crystals. In contrast to previous observations of hyperbolic phonon-polaritons using crystals with a symmetric structure, the team discovered new properties of the shear polaritons: their propagation direction depends on the infrared wavelength and their wave fronts are tilted. Optical shear phenomena are found responsible for these new features, which exclusively arise because of the lower crystal symmetry and the associated alignment of the lattice vibrations. Therefore, the crystal symmetry is the fundamental reason for these discoveries.
“We expect that our results will open new avenues for polariton physics in materials with low symmetry which include many geological minerals and organic crystals”, says Paarmann. This will provide a much greater choice of materials for technological development, which will substantially enhance design options for compact photonic components. This means a big step forward for miniaturization of optical circuitry in future nanophotonic technology.