Probing of sub-picometer vertical differential resolutions using cavity plasmons

Chen, Wen; Zhang, Shunping; Deng, Qian; Xu, Hongxing

doi:10.1038/s41467-018-03227-7

Cited by 98 publications

(105 citation statements)

References 37 publications

(47 reference statements)

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“…Second, as the spectral response is highly sensitive to material and environmental parameters [see, for example, Fig. 3(b)], it may be adapted for a plasmonic ruler or sensing down on the nanometer scale [37]. Third, the rapid coherent energy exchange of the strongly coupled structure could find promising applications in dark-mode-based plasmonic devices and ultrafast optical processes, which may also be intermediated via the nanorod dipole from the optical far field.…”

Section: Resultsmentioning

confidence: 99%

Dark dimer mode excitation and strong coupling with a nanorod dipole

et al. 2018

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We theoretically investigate dark dimer mode excitation and strong coupling with a nanorod dipole. Efficient excitation of a dark mode in a gold (Au) nanorod dimer using an electric dipole can be achieved by an optimal overlap between the dipole moment and dark modal field. By replacing the dipole emitter with an Au nanorod, a plane wave excited dipole mode in the nanorod can be effectively coupled to the dark dimer mode through nearfield interaction. At a 10-nm separation of the nanorod and the dimer, plasmonic interaction between dipole-dark modes enters the strong coupling regime with a Rabi-like splitting of 219.2 meV, which is further evidenced by the anticrossing feature and Rabi-like oscillation of electromagnetic energy of the coupled modes. Our results propose an efficient approach to far-field activating dark modes in coupled nanorod dimers and exchanging plasmonic excitations at nanoscale, which may open new opportunities for nanoplasmonic applications such as nanolasers or nanosensors.

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Section: Resultsmentioning

confidence: 99%

Dark dimer mode excitation and strong coupling with a nanorod dipole

et al. 2018

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“…The gap‐plasmon mode increases as the gap between the plasmonic NPs decreases to form a nanogap. [ 22 ] When the nanogaps are formed, small metallic NPs can be used to invoke a plasmonic enhancement effect at long wavelengths of around 600 nm. When the plasmonic NPs are oriented in nanogap assemblies, such as in the case of NP‐M13 biohybrid nanostructures, there is a corresponding redshift in the optical absorption spectra ( Figure a) and LSPR spectra (Figure 3b).…”

Section: Figurementioning

confidence: 99%

Gap Plasmon of Virus‐Templated Biohybrid Nanostructures Uplifting the Performance of Organic Optoelectronic Devices

Lee

Kim

Lee

et al. 2020

Advanced Optical Materials

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As demonstrated by Jin‐Woo Oh, Jae‐Wook Kang and co‐workers in article number 1902080, the M13 bacteriophage can be used as a biological scaffold for the controlled densification of silver and gold nanoparticles, yielding a novel biohybrid nanostructure with fascinating gap‐plasmon effect. The binder‐free, charge driven synthesis mechanism of the nanostructures is presented. The resulting phage nanostructural network is successfully applied as a bifunctional optical enhancer–interfacial layer in organic solar cells and organic light‐emitting diodes.

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“…The noble metal nanostructures have significantly superior surface plasmon resonance absorption, which is caused by the collective excitation of electrons caused by incident electromagnetic radiation near the metal-dielectric interface and coherent oscillation along the surface [86][87][88][89][90]. With the continuous deepening of the research on surface plasmon and the constant advancement of nano-processing technology, we can accommodate different applications through good control of material morphology [91].…”

Section: Noble Metal Nanostructures For Sersmentioning

confidence: 99%

Recent progress in periodic patterning fabricated by self-assembly of colloidal spheres for optical applications

Liu

Zhang

et al. 2020

Sci. China Mater.

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Colloidal crystals are periodically ordered arrays of monodisperse colloidal particles which represent a new class of self-assembled materials showing potential applications in many fields. Two-dimensional graphic nanostructures based on colloidal crystals have inherent periodicity from tens of nanometers to several micrometers, which gives them rich and interesting optical properties. This article presents a comprehensive review about the current research activities on the self-assembly of colloidal spheres which is an effective strategy for fabrication of various hierarchical and ordered nanostructures, with particular attention paid to the unique properties and applications of the colloidal crystal-based nanostructures. Three main aspects are elaborated: a) controllable self-assembly of colloidal crystals; b) the functions of the obtained colloidal spheres acting as the patterned mask for successive construction of numerous nanostructures; c) the novel properties and promising optical applications of the patterned nanostructures in various domains, such as plasmonic-related fields, antireflection, photonic crystals, photocatalysis and electronic devices. After that, the current challenges and future perspectives in this area are provided. This review aims to inspire more ingenious designs and exciting research for manufacturing nanostructures utilizing colloidal self-assembly.

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Probing of sub-picometer vertical differential resolutions using cavity plasmons

Cited by 98 publications

References 37 publications

Dark dimer mode excitation and strong coupling with a nanorod dipole

Dark dimer mode excitation and strong coupling with a nanorod dipole

Gap Plasmon of Virus‐Templated Biohybrid Nanostructures Uplifting the Performance of Organic Optoelectronic Devices

Recent progress in periodic patterning fabricated by self-assembly of colloidal spheres for optical applications

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