Photonic Hook Plasmons: A New Curved Surface Wave

Minin, Igor V.; Minin, Oleg V.; Пономарев, Д. С.; Glinskiy, I. A.

doi:10.1002/andp.201800359

Cited by 38 publications

(21 citation statements)

References 35 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…However, the addition of the wedge creates the asymmetric structure that curves the light upon exiting the cuboid to a degree dependent on the wedge angle. Wavefront analysis of such asymmetric mesoscale structure reveals that the unequal phase of the transmitted plane wave results in the irregularly concave deformation of the wavefront inside the structure that then leads to creation of the PH [33][34][35][36][37][38], which can be more easily visualized as a light beam with astigmatism on the macro scale. A distinctive feature of the PH are: the radius of curvature of PH is the fraction of illumination wavelength and although the curved profile evokes a similarity with Airy beams, in contrast to Airy beams there are no curved side lobes [34][35][36][37], where in the caustic from one side the sidelobes almost parallel to each other.…”

Section: Photonic Hook: a New Subwavelength Self-bending Structured Lmentioning

confidence: 99%

“…3). Recent studies have investigated the generation of wide families of photonic hook beams, bringing many future opportunities to this fast-moving area including optics [33][34][35]37], THz [36], surface plasmon photonics (SPP) [38], acoustics [39] and have boosted the development of mesoscale photonics providing cuttingedge abilities in particle manipulation on subwavelength scales.…”

Section: Photonic Hook: a New Subwavelength Self-bending Structured Lmentioning

confidence: 99%

See 1 more Smart Citation

Recent Trends in Optical Manipulation Inspired by Mesoscale Photonics and Diffraction Optics

Minin

2020

J-BPE

Self Cite

View full text Add to dashboard Cite

The spatial resolution of conventional optics, which is need for nondestructively trapping of microobjects, is limited by diffraction to nearly half the wavelength. Despite this limitation, the use of optical methods is one of the main directions in biological and biomedical researches, since only the use of optical methods has a minimal effect on living organisms. Quick progress in this field is based on a large extent on the development of new optical technologies and significant progress in the mesoscale photonics enabled the researches to obtain novel, previously unachievable information. Below we discussed some recent trends in optical manipulations on wavelength scale based on diffractive elements mesoscale dielectric particles as a field localization object and classical diffractive optical elements with unusual properties.

show abstract

Section: Photonic Hook: a New Subwavelength Self-bending Structured Lmentioning

confidence: 99%

Section: Photonic Hook: a New Subwavelength Self-bending Structured Lmentioning

confidence: 99%

Recent Trends in Optical Manipulation Inspired by Mesoscale Photonics and Diffraction Optics

Minin

2020

J-BPE

Self Cite

View full text Add to dashboard Cite

show abstract

“…Although the term "PNJ" was originally coined for the concentrated beam regarding microspheres, it has been generalized immensely to also represent the squeezed eld on the shadow surface of non-spherical objects, such as cuboids, triangles, gratings, and nanober assemblies. [32][33][34][35] Such a generalization facilitates the explanation and description of the light-matter interaction for non-spherical objects in the PNJ language. The emergence of novel light sources including frequency combs, 36 ultra-fast lasers, 37 super-continuum sources, 38 and quantum atom-ber photonics, 39 provide a brandnew dimension for the PNJ generators (microsphere and its derivatives) to manipulate light-matter interaction in extreme environments.…”

Section: Introductionmentioning

confidence: 99%

All-dielectric concentration of electromagnetic fields at the nanoscale: the role of photonic nanojets

Zhu

Goddard

2019

Nanoscale Adv.

View full text Add to dashboard Cite

show abstract

“…DOI: 10.21883/OS.2019.05.47665. [14][15][16][17][18][19] Введение С конца ХХ века наблюдается значительное развитие методов терагерцовой (ТГц) визуализации [1]. Среди приложений ТГц изображающих систем особый интерес представляет медицинская диагностика [2,3] и, в частности, дифференциация здоровых тканей и злокачественных новообразований различной нозологии и локали-зации с использованием ТГц имиджинга на основе эндогенных (естественных) маркеров [4][5][6].…”

unclassified

“…Другая группа методов построения высокоразрешающих ТГц изображающих систем основана на эффекте локализации электромагнитного поля позади диэлектрических объектов различной геометрии [13]. В частности, для достижения субволнового разрешения могут быть использованы субволновые каустики ТГц излучения, формируемые позади мезомасштабных диэлектрических или металлических частиц (например, сфер, кубиков или асимметричных частиц) -так называемые " тераструи" (tera-jets) [14][15][16][17][18]. Так, в работах [19,20] достигнуто пространственное разрешение до 0.5λ, при этом использовались мезоразмерные частицы, изготовленные как из однородного материала, так и из метаматериалов с искусственно подобранными диэлектрическими свойствами [21].…”

unclassified

Терагерцовый Микроскоп На Основе Эффекта Твердотельной Иммерсии Для Визуализации Биологических Тканей-=sup=-*-=/Sup=-

Черномырдин¹,

Кучерявенко²,

Римская³

et al. 2019

Журнал Технической Физики

View full text Add to dashboard Cite

A novel method of terahertz (THz) microscopy was proposed for imaging of biological tissues with sub-wavelength spatial resolution. It allows for overcoming the Abbe diffraction limit and provides a sub-wavelength resolution thanks to the solid immersion effect – i.e. to the reduction in the dimensions of electromagnetic beam caustic, when the beam is focused in free space, at a small distance (smaller than the wavelength) behind the medium featuring high refractive index. An experimental setup realizing the proposed method was developed. It uses a backward wave oscillator, as a THz-wave emitter, and a Golay cell, as a THz-wave detector. In this setup, the radiation is focused behind the silicon hemisphere in order to realize the solid immersion effect. The spatial resolution of 0.15λ was demonstrated for the developed microscope, while the measurements were carried out at the wavelength of λ=500 μm, with the metal-air interface as a test object. Such a high spatial resolution represents a significant advantage over that of the previously reported arrangements of solid immersion microscopes. The solid immersion microscopy does not imply using any diaphragms or other near-field probes for achieving the sub-wavelength spatial resolution; thus, it eliminates the energy losses associated with such elements. The proposed methods were applied for imaging of biological tissues, and the observed results highlight its potential in biology and medicine.

show abstract

Photonic Hook Plasmons: A New Curved Surface Wave

Cited by 38 publications

References 35 publications

Recent Trends in Optical Manipulation Inspired by Mesoscale Photonics and Diffraction Optics

Recent Trends in Optical Manipulation Inspired by Mesoscale Photonics and Diffraction Optics

All-dielectric concentration of electromagnetic fields at the nanoscale: the role of photonic nanojets

Терагерцовый Микроскоп На Основе Эффекта Твердотельной Иммерсии Для Визуализации Биологических Тканей-=sup=-*-=/Sup=-

Contact Info

Product

Resources

About