Author
Listed:
- Yi Yang
(Massachusetts Institute of Technology)
- Di Zhu
(Massachusetts Institute of Technology)
- Wei Yan
(Université Bordeaux, CNRS
Westlake University
Westlake University)
- Akshay Agarwal
(Massachusetts Institute of Technology)
- Mengjie Zheng
(Massachusetts Institute of Technology
Hunan University)
- John D. Joannopoulos
(Massachusetts Institute of Technology)
- Philippe Lalanne
(Université Bordeaux, CNRS)
- Thomas Christensen
(Massachusetts Institute of Technology)
- Karl K. Berggren
(Massachusetts Institute of Technology)
- Marin Soljačić
(Massachusetts Institute of Technology)
Abstract
The macroscopic electromagnetic boundary conditions, which have been established for over a century1, are essential for the understanding of photonics at macroscopic length scales. Even state-of-the-art nanoplasmonic studies2–4, exemplars of extremely interface-localized fields, rely on their validity. This classical description, however, neglects the intrinsic electronic length scales (of the order of ångström) associated with interfaces, leading to considerable discrepancies between classical predictions and experimental observations in systems with deeply nanoscale feature sizes, which are typically evident below about 10 to 20 nanometres5–10. The onset of these discrepancies has a mesoscopic character: it lies between the granular microscopic (electronic-scale) and continuous macroscopic (wavelength-scale) domains. Existing top-down phenomenological approaches deal only with individual aspects of these omissions, such as nonlocality11–13 and local-response spill-out14,15. Alternatively, bottom-up first-principles approaches—for example, time-dependent density functional theory16,17—are severely constrained by computational demands and thus become impractical for multiscale problems. Consequently, a general and unified framework for nanoscale electromagnetism remains absent. Here we introduce and experimentally demonstrate such a framework—amenable to both analytics and numerics, and applicable to multiscale problems—that reintroduces the electronic length scale via surface-response functions known as Feibelman d parameters18,19. We establish an experimental procedure to measure these complex dispersive surface-response functions, using quasi-normal-mode perturbation theory and observations of pronounced nonclassical effects. We observe nonclassical spectral shifts in excess of 30 per cent and the breakdown of Kreibig-like broadening in a quintessential multiscale architecture: film-coupled nanoresonators, with feature sizes comparable to both the wavelength and the electronic length scale. Our results provide a general framework for modelling and understanding nanoscale (that is, all relevant length scales above about 1 nanometre) electromagnetic phenomena.
Suggested Citation
Yi Yang & Di Zhu & Wei Yan & Akshay Agarwal & Mengjie Zheng & John D. Joannopoulos & Philippe Lalanne & Thomas Christensen & Karl K. Berggren & Marin Soljačić, 2019.
"A general theoretical and experimental framework for nanoscale electromagnetism,"
Nature, Nature, vol. 576(7786), pages 248-252, December.
Handle:
RePEc:nat:nature:v:576:y:2019:i:7786:d:10.1038_s41586-019-1803-1
DOI: 10.1038/s41586-019-1803-1
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Cited by:
- Ian Aupiais & Romain Grasset & Tingwen Guo & Dmitri Daineka & Javier Briatico & Sarah Houver & Luca Perfetti & Jean-Paul Hugonin & Jean-Jacques Greffet & Yannis Laplace, 2023.
"Ultrasmall and tunable TeraHertz surface plasmon cavities at the ultimate plasmonic limit,"
Nature Communications, Nature, vol. 14(1), pages 1-9, December.
- Valerio Di Giulio & P. A. D. Gonçalves & F. Javier García de Abajo, 2022.
"An image interaction approach to quantum-phase engineering of two-dimensional materials,"
Nature Communications, Nature, vol. 13(1), pages 1-8, December.
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