scholarly journals Fourier-component engineering to control light diffraction beyond subwavelength limit

Nanophotonics ◽  
2021 ◽  
Vol 0 (0) ◽  
Author(s):  
Sun-Goo Lee ◽  
Seong-Han Kim ◽  
Chul-Sik Kee
Keyword(s):  
Bound States ◽  
Fourier Component ◽  
Light Diffraction ◽  
Fano Resonances ◽  
Multiple Diffraction ◽  
Great Ability ◽  
Resonance Effects ◽  
Fourier Harmonic ◽  
Highly Efficient ◽  
Physical Phenomena

Abstract Resonant physical phenomena in planar photonic lattices, such as bound states in the continuum (BICs) and Fano resonances with 100% diffraction efficiency, have garnered significant scientific interest in recent years owing to their great ability to manipulate electromagnetic waves. In conventional diffraction theory, a subwavelength period is considered a prerequisite to achieving the highly efficient resonant physical phenomena. Indeed, most of the previous studies, that treat anomalous resonance effects, utilize quasiguided Bloch modes at the second stop bands open in the subwavelength region. Higher (beyond the second) stop bands open beyond the subwavelength limit have attracted little attention thus far. In principle, resonant diffraction phenomena are governed by the superposition of scattering processes, owing to higher Fourier harmonic components of periodic modulations in lattice parameters. But only some of Fourier components are dominant at band edges with Bragg conditions. Here, we present new principles of light diffraction, that enable identification of the dominant Fourier components causing multiple diffraction orders at the higher stopbands, and show that unwanted diffraction orders can be suppressed by engineering the dominant Fourier components. Based on the new diffraction principles, novel Fourier-component-engineered (FCE) metasurfaces are introduced and analyzed. It is demonstrated that these FCE metasurfaces with appropriately engineered spatial dielectric functions can exhibit BICs and highly efficient Fano resonances even beyond the subwavelength limit.

scholarly journals Active nonlocal metasurfaces

Nanophotonics ◽  
2020 ◽  
Vol 10 (1) ◽  
pp. 655-665
Author(s):  
Stephanie C. Malek ◽  
Adam C. Overvig ◽  
Sajan Shrestha ◽  
Nanfang Yu
Keyword(s):  
Bound States ◽  
Fano Resonances ◽  
Spatial Control ◽  
Technical Challenge ◽  
Materials Engineering ◽  
Narrow Bandwidth ◽  
Wavefront Shaping ◽  
Mechanical Stretching ◽  
Proof Of Principle ◽  
The Continuum

AbstractActively tunable and reconfigurable wavefront shaping by optical metasurfaces poses a significant technical challenge often requiring unconventional materials engineering and nanofabrication. Most wavefront-shaping metasurfaces can be considered “local” in that their operation depends on the responses of individual meta-units. In contrast, “nonlocal” metasurfaces function based on the modes supported by many adjacent meta-units, resulting in sharp spectral features but typically no spatial control of the outgoing wavefront. Recently, nonlocal metasurfaces based on quasi-bound states in the continuum have been shown to produce designer wavefronts only across the narrow bandwidth of the supported Fano resonance. Here, we leverage the enhanced light-matter interactions associated with sharp Fano resonances to explore the active modulation of optical spectra and wavefronts by refractive-index tuning and mechanical stretching. We experimentally demonstrate proof-of-principle thermo-optically tuned nonlocal metasurfaces made of silicon and numerically demonstrate nonlocal metasurfaces that thermo-optically switch between distinct wavefront shapes. This meta-optics platform for thermally reconfigurable wavefront shaping requires neither unusual materials and fabrication nor active control of individual meta-units.

scholarly journals The dialectic of history and science

2018 ◽  
Vol 222 (2) ◽  
pp. 27-45
Author(s):  
Dr. Darradji Zarroukhi Lecteurer
Keyword(s):  
Scientific Explanation ◽  
Natural Sciences ◽  
Self Control ◽  
Scientific Thinking ◽  
Philosophical Thinking ◽  
Current Form ◽  
Great Ability ◽  
Science Of History ◽  
Scientific Approach ◽  
Physical Phenomena

    Scientific research is characterized by rigor, methodology and objectivity, and requires a lot of attention and care. It calls for continuous efforts and great ability of imagination, perseverance and self-control. But before the develloping the scientific approach in its current form, mankind used another kind of thinking, known philosophical thinking . If the scientific thinking is judged as organized and unified thinking, this does not mean that philosophical thinking is unorganized. It is a thinking subject to logical standards, and take into account the consistency of introductions with the final results. Moreover, the philosophical thinking gives more freedom to the mind and less constrained by the standard and controls and it is characterized by a kind of totalitarianism. The separation of scientific thinking came after the maturity of scientific methods, which rationalized and quantified the phenomena and their interpretations. The maturuty of the scientific thinking comes from the succes of natural Sciences, which dealt with realistic physical phenomena and it based on scientistic experimental approach as a way to understand and interpret physical phenomena. After the stunning success of the natural sciences, some scientists and thinkers try the application of the experimental methods in the study of historical phenomena which led to the separation between the history of the philosophy. However, the history subjects differ from those of the natural sciences. they are more complex and interconnected, and this is what made the scientific study of the historical phenomena known several epistemological obstacles preventing the rationalization of the historical phenomena, driving a skepticism in the value of the science of history and its ability to interpret historical phenomena using only scientific explanation without the philosophical interpretation. or is it that historical studies should return to the field of philosophy. This is what I tried to explain it through this article that addresses the following issue: Did the historical studies respect canonical scientific approach

scholarly journals High Quality-Factor Dual-Band Fano Resonances Induced by Bound States in The Continuum Using A Planar Nanohole Slab

2021 ◽  
Author(s):  
Tian Sang ◽  
Qing Mi ◽  
Yao Pei ◽  
Chaoyu Yang ◽  
Shi Li ◽  
...  
Keyword(s):  
Bound States ◽  
Near Field ◽  
Dual Band ◽  
Q Factor ◽  
Fano Resonances ◽  
High Quality ◽  
Potential Applications ◽  
Q Factors ◽  
Symmetry Protected ◽  
The Continuum

Abstract In photonics, it is essential to achieve high quality (Q)-factor resonances to enhance light-mater interactions for improving performances of optical devices. Herein, we demonstrate that high Q-factor dual-band Fano resonances can be achieved by using a planar nanohole slab (PNS) based on the excitation of bound states in the continuum (BICs). By shrinking or expanding the tetramerized holes of the superlattice of the PNS, symmetry-protected BICs can be excited and the locations of Fano resonances as well as their Q-factors can be flexibly tuned. Physical mechanisms for the dual-band Fano resonances can be interpreted as the resonant couplings between the electric-toroidal dipoles or the magnetic-toroidal dipoles based on the far-field multiple decompositions and the near-field distributions of the superlattice. The dual-band Fano resonances of the PNS possess polarization independent feature, they can be survived even the geometric parameters of the PNS are significantly altered, making them more suitable for potential applications.

scholarly journals Multipole and multimode engineering in Mie resonance-based metastructures

Nanophotonics ◽  
2020 ◽  
Vol 9 (5) ◽  
pp. 1115-1137 ◽  
Author(s):  
Tianji Liu ◽  
Rongyang Xu ◽  
Peng Yu ◽  
Zhiming Wang ◽  
Junichi Takahara
Keyword(s):  
Bound States ◽  
Multimodal Interaction ◽  
Low Loss ◽  
Mie Resonance ◽  
Lattice Mode ◽  
Light Matter Interaction ◽  
Developing Area ◽  
Meta Atom ◽  
Novel Applications ◽  
Physical Phenomena

AbstractBenefited from the well-known Mie resonance, a plethora of physical phenomena and applications are attracting attention in current research on dielectric-based nanophotonics. High-index dielectric metastructures are favorable to enhance light-matter interaction in nanoscale with advantages such as low loss, optical magnetism, and multipolar responses, which are superior to their plasmonic counterpart. In this review, we highlight the important role played by Mie resonance-based multipolar and multimodal interaction in nanophotonics, introducing the concept of “multipole and multimode engineering” in artificially engineered dielectric-based metastructures and providing an overview of the recent progress of this fast-developing area. The scope of multipole and multimode engineering is restricted not only in multipolar interferences of meta-atom and meta-molecule but also in the nontrivial intermodal coupling (Fano resonance and bound states in the continuum), in the collective mode and the surface lattice mode appearing via periodic meta-lattices and aperiodic meta-assembly, in chiral enhancement via chiral and achiral dielectric metastructures, and in Mie resonance-mediated hybrid structures (Mie-plasmon and Mie-exciton). Detailed examples and the underlying physics of this area are discussed in-depth, in order to lead the multifunctional metastructures for novel applications in the future.

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