| Literature DB >> 31427747 |
Archana Raja1,2, Lutz Waldecker3,4, Jonas Zipfel5, Yeongsu Cho6, Samuel Brem7, Jonas D Ziegler5, Marvin Kulig5, Takashi Taniguchi8, Kenji Watanabe8, Ermin Malic7, Tony F Heinz3,4, Timothy C Berkelbach9,10, Alexey Chernikov11.
Abstract
Understanding and controlling disorder is key to nanotechnology and materials science. Traditionally, disorder is attributed to local fluctuations of inherent material properties such as chemical and structural composition, doping or strain. Here, we present a fundamentally new source of disorder in nanoscale systems that is based entirely on the local changes of the Coulomb interaction due to fluctuations of the external dielectric environment. Using two-dimensional semiconductors as prototypes, we experimentally monitor dielectric disorder by probing the statistics and correlations of the exciton resonances, and theoretically analyse the influence of external screening and phonon scattering. Even moderate fluctuations of the dielectric environment are shown to induce large variations of the bandgap and exciton binding energies up to the 100 meV range, often making it a dominant source of inhomogeneities. As a consequence, dielectric disorder has strong implications for both the optical and transport properties of nanoscale materials and their heterostructures.Year: 2019 PMID: 31427747 DOI: 10.1038/s41565-019-0520-0
Source DB: PubMed Journal: Nat Nanotechnol ISSN: 1748-3387 Impact factor: 39.213