Controlling the Infrared Dielectric Function through Atomic-Scale Heterostructures

Daniel C. Ratchford, Christopher J. Winta, Ioannis Chatzakis, Chase T. Ellis, Nikolai C. Passler, Jonathan Winterstein, Pratibha Dev, Ilya Razdolski, Joseph R. Matson, Joshua R. Nolen, Joseph G. Tischler, Igor Vurgaftman, Michael B. Katz, Neeraj Nepal, Matthew T. Hardy, Jordan A. Hachtel, Juan Carlos Idrobo, Thomas L. Reinecke, Alexander J. Giles, D. Scott KatzerNabil D. Bassim, Rhonda M. Stroud, Martin Wolf, Alexander Paarmann, Joshua D. Caldwell

Research output: Contribution to journalArticlepeer-review

34 Scopus citations

Abstract

Surface phonon polaritons (SPhPs), the surface-bound electromagnetic modes of a polar material resulting from the coupling of light with optic phonons, offer immense technological opportunities for nanophotonics in the infrared (IR) spectral region. However, once a particular material is chosen, the SPhP characteristics are fixed by the spectral positions of the optic phonon frequencies. Here, we provide a demonstration of how the frequency of these optic phonons can be altered by employing atomic-scale superlattices (SLs) of polar semiconductors using AlN/GaN SLs as an example. Using second harmonic generation (SHG) spectroscopy, we show that the optic phonon frequencies of the SLs exhibit a strong dependence on the layer thicknesses of the constituent materials. Furthermore, new vibrational modes emerge that are confined to the layers, while others are centered at the AlN/GaN interfaces. As the IR dielectric function is governed by the optic phonon behavior in polar materials, controlling the optic phonons provides a means to induce and potentially design a dielectric function distinct from the constituent materials and from the effective-medium approximation of the SL. We show that atomic-scale AlN/GaN SLs instead have multiple Reststrahlen bands featuring spectral regions that exhibit either normal or extreme hyperbolic dispersion with both positive and negative permittivities dispersing rapidly with frequency. Apart from the ability to engineer the SPhP properties, SL structures may also lead to multifunctional devices that combine the mechanical, electrical, thermal, or optoelectronic functionality of the constituent layers. We propose that this effort is another step toward realizing user-defined, actively tunable IR optics and sources.

Original languageEnglish
Pages (from-to)6730-6741
Number of pages12
JournalACS Nano
Volume13
Issue number6
DOIs
StatePublished - Jun 25 2019

Funding

D.C.R., C.T.E., J.G.T., I.V., T.R., N.N., A.J.G., D.S.K., N.D.B., M.T.H., R.M.S., and J.D.C. were supported by the Office of Naval Research through the U.S. Naval Research Laboratory and administered by the NRL Nanoscience Institute. J.D.C. and D.C.R. would like to express their sincere gratitude to Dr. Thomas Tiwald of J.A. Woollam, Inc. for the insight and assistance in performing the dielectric function fitting of the SLs explored in this work. C.J.W., N.C.P., I.R., and A.P. would like to thank Wieland Schoellkopf and Sandy Gewinner for operating the IR-FEL. P.D. acknowledges support from NRL through the ONR Summer Faculty Program. Computer resources were provided by the DoD High Performance Computing Modernization Program. I.C., J.W., and M.K. acknowledge support from the NRC/ASEE Postdoctoral Fellowship at NRL. C.T.E. acknowledges support from the U.S. Naval Research Laboratory, Karles Fellowship. Microscopy research was performed as part of a user proposal at Oak Ridge National Laboratory’s Center for Nanophase Materials Sciences (CNMS), which is a U.S. Department of Energy, Office of Science User Facility at the Oak Ridge National Laboratory.

FundersFunder number
NRC/ASEE
NRL Nanoscience Institute
Office of Naval Research
U.S. Naval Research Laboratory

    Keywords

    • Surface phonon polaritons
    • infrared
    • interface phonon
    • optic phonons
    • polar semiconductor
    • second harmonic generation
    • superlattice

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