Generation of spatiotemporally tailored terahertz wavepackets by nonlinear metasurfaces

The past two decades have witnessed an ever-growing number of emerging applications that utilize terahertz (THz) waves, ranging from advanced biomedical imaging, through novel security applications, fast wireless communications, and new abilities to study and control matter in all of its phases. The...

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Bibliographic Details
Published in:Nature communications 2019-04, Vol.10 (1), p.1778-1778, Article 1778
Main Authors: Keren-Zur, Shay, Tal, Mai, Fleischer, Sharly, Mittleman, Daniel M., Ellenbogen, Tal
Format: Article
Language:English
Subjects:
639/624/400/1021
639/624/400/385
639/624/400/561
639/925/357/1015
Broadband
Emitters
Fourier transforms
Humanities and Social Sciences
Medical imaging
Metasurfaces
multidisciplinary
New technology
Quadrupoles
Radiation
Science
Science (multidisciplinary)
Security
Terahertz frequencies
Wave propagation
Wireless communications
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Summary:The past two decades have witnessed an ever-growing number of emerging applications that utilize terahertz (THz) waves, ranging from advanced biomedical imaging, through novel security applications, fast wireless communications, and new abilities to study and control matter in all of its phases. The development and deployment of these emerging technologies is however held back, due to a substantial lack of simple methods for efficient generation, detection and manipulation of THz waves. Recently it was shown that uniform nonlinear metasurfaces can efficiently generate broadband single-cycle THz pulses. Here we show that judicious engineering of the single-emitters that comprise the metasurface, enables to obtain unprecedented control of the spatiotemporal properties of the emitted THz wavepackets. We specifically demonstrate generation of propagating spatiotemporal quadrupole and few-cycles THz pulses with engineered angular dispersion. Our results place nonlinear metasurfaces as a new promising tool for generating application-tailored THz fields with controlled spatial and temporal characteristics. While the terahertz range has become increasingly important for a wide range of applications, efficient sources with bespoke output characteristics are still lacking. Here, Keren-Zur et al . show that engineering of a metasurface’s individual elements allows control of the spatiotemporal properties of the emitted terahertz radiation.
ISSN:2041-1723
2041-1723
DOI:10.1038/s41467-019-09811-9