New material generates spin and orbital angular momenta from a linearly polarized incident beam

Abstract Metallic plasmonic probes have been successfully applied in near-field imaging, nanolithography, and Raman enhanced spectroscopy because of their ability to squeeze light into nanoscale and provide significant electric field enhancement. Most of these probes rely on nanometric alignment of incident beam and resonant structures with limited spectral bandwidth. This paper proposes and experimentally demonstrates an asymmetric fiber tip for broadband interference nanofocusing within its full optical wavelengths (500–800 nm) at the nanotip with 10 nm apex. The asymmetric geometry consisting of two semicircular slits rotates plasmonic polarization and converts the linearly polarized plasmonic mode to the radially polarized plasmonic mode when the linearly polarized beam couples to the optical fiber. The three-dimensional plasmonic modulation induces circumference interference and nanofocus of surface plasmons, which is significantly different from the nanofocusing through plasmon propagation and plasmon evolution. The plasmonic interference modulation provides fundamental insights into the plasmon engineering and has important applications in plasmon nanophotonic technologies.

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Determination of the Pu autoionizing level angular momenta by a multistep excitation with linearly polarized laser light

Optics Communications ◽

10.1016/s0030-4018(99)00558-1 ◽

1999 ◽

Vol 171 (4-6) ◽

pp. 253-261 ◽

Cited By ~ 3

Author(s):

M.P. Chernomorets ◽

M.V. Dubov ◽

G.V. Klishevich

Keyword(s):

Laser Light ◽

Angular Momenta ◽

Linearly Polarized

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Periodic Alignment of Silicon Dot Fabricated by Linearly Polarized Nd:YAG Pulse Laser

MRS Proceedings ◽

10.1557/proc-0910-a15-03 ◽

2006 ◽

Vol 910 ◽

Author(s):

Kensuke Nishioka ◽

Susumu Horita

Keyword(s):

Thin Film ◽

Energy Density ◽

Laser Beam ◽

Density Distribution ◽

Pulse Laser ◽

Incident Beam ◽

Sio2 Film ◽

Energy Density Distribution ◽

Linearly Polarized ◽

Si Thin Film

AbstractPeriodically aligned submicron Si dots were fabricated by only irradiating linearly polarized Nd:YAG pulse laser to the amorphous silicon (a-Si) thin film deposited on silicon dioxide (SiO2) film. Interference between the incident beam and the scattered surface wave leads to the spatial periodicity of beam energy density distribution on the surface of the irradiated samples. The a-Si thin film was melted by laser beam, and then, the molten thin Si film was split and condensed due to its surface tensile according to the periodic energy density distribution. The polycrystalline Si (poly-Si) fine lines were formed periodically. After the first irradiation, the sample was rotated by 90o, and the laser beam was irradiated. The periodic energy density distribution was generated on the Si fine lines. Then, the lines were split off and condensed according to the periodic energy density distribution, and the periodically aligned submicron Si dots were fabricated on the SiO2 film.

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Spatial modifications of three-dimensional elliptic Gaussian beam scattered by two-dimensional periodic array.

Advanced Electromagnetics ◽

10.7716/aem.v1i1.8 ◽

2012 ◽

Vol 1 (1) ◽

pp. 11

Author(s):

A. Gribovsky ◽

O. Yeliseyev

Keyword(s):

Gaussian Beam ◽

Antenna Array ◽

Cross Section ◽

Periodic Structures ◽

Diffraction Problem ◽

Three Dimensional ◽

Incident Beam ◽

Two Dimensional ◽

Transmitted Beam ◽

Linearly Polarized

The diffraction problem of a three-dimensional elliptic p- polarized Gaussian beam on an aperture array of rectangular holes is solved. The new algorithm for the solution of three-dimensional scattering problems of linearly polarized wave beams on two-dimensional periodic structures is offered. The given algorithm allows exploring of wave beams with any allocation of a field on cross section. The case of oblique incidence of linearly polarized elliptic Gaussian wave beam on two-dimensional periodic structure is viewed. As structure the rectangular waveguides phased antenna array is chosen. The elliptic shape of a beam cross section gives the chance to proportion energy of an incident field in a plane of an antenna array in the chosen direction. The frequency dependence of the reflection coefficient intensity for the Gaussian beam is calculated. For the analysis of patterns of the reflected and transmitted beams in a far zone the frequencies on which the strongest interaction between next waveguides channels is observed have been chosen. Dynamics of patterns transformation of the reflected and transmitted beams depending on the form of cross-section and a polarization direction of an incident beam on different frequencies is investigated. It is determined that shape of the pattern of reflected and transmitted beams (symmetry, asymmetry, bifurcation, amplitude, width) depends on chosen spatial orientation of the ellipse axes of the cross section in the incident beam. Frequency ranges, in which the form of the reflected and transmitted beams is not Gaussian, are defined. The nature of transformation of the patterns of scattered beams was examined. Narrowing effect of the pattern of transmitted beam and deformation of the pattern of reflected beam is detected. A physical explanation of these effects is given. The results are presented in the form of two- and three-dimensional patterns of the scattered field of beams in the far field.

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Direct Simulation of Scattering and Absorption by Particle Deposits

Heat Transfer, Volume 1 ◽

10.1115/imece2006-14615 ◽

2006 ◽

Cited By ~ 1

Author(s):

Daniel W. Mackowski

Keyword(s):

Large Scale ◽

Incident Beam ◽

Amplitude Distribution ◽

Addition Theorem ◽

Spherical Particles ◽

Direct Simulation ◽

Vector Spherical Harmonic ◽

Linearly Polarized ◽

Scattered Fields ◽

Radiative Absorption

A computational scheme is presented to exactly calculate the electromagnetic field distribution, and associated radiative absorption and scattering characteristics, of large-scale ensembles of spherical particles that are subjected to a focussed incident beam. The method employs a superposition extension to Lorenz/Mie theory, in which the internal and scattered fields for each sphere in the ensemble are represented by vector spherical harmonic expansions, and boundary conditions at the surfaces of the spheres are matched by application of the addition theorem for vector harmonics. The incident field is modeled as a transverse, linearly-polarized wave with a Gaussian amplitude distribution along a fixed focal plane. Application of the method to prediction of the absorption and reflectance characteristics of particle deposits is discussed, and illustrative calculations are presented.

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Fabrication of Periodic Arrays of Nano-sized Si and Ni dots on SiO2 Using Linearly Polarized Nd:YAG Pulsed Laser

MRS Proceedings ◽

10.1557/proc-1059-kk08-09 ◽

2007 ◽

Vol 1059 ◽

Author(s):

Kensuke Nishioka ◽

Susumu Horita

Keyword(s):

Energy Density ◽

Laser Beam ◽

Density Distribution ◽

Pulsed Laser ◽

Incident Beam ◽

Space Structure ◽

Energy Density Distribution ◽

Periodic Arrays ◽

Beam Energy Density ◽

Linearly Polarized

ABSTRACTPeriodic arrays of nano-sized Si and Ni dots were fabricated by only irradiating a linearly polarized Nd:YAG pulsed laser beam to Si and Ni thin films deposited on silicon dioxide (SiO2) film. The interference between an incident beam and a scattered surface wave leads to the spatial periodicity of beam energy density distribution on the surface of the irradiated samples. A thin film was melted using a laser beam, and the molten film was split and condensed owing to its surface tensile according to the periodic energy density distribution. Then, the fine lines (line and space structure) were formed periodically. After the formation of fine lines, the sample was rotated by 90°, and the laser beam was irradiated. The periodic energy density distribution was generated on the fine lines, and the lines split and condensed according to the periodic energy density distribution. Eventually, the periodically aligned nano-sized dots were fabricated on the SiO2 film.

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Об эффекте Гуса-Хенхена при наличии возбуждения поверхностных волн в схеме Кречмана

Журнал технической физики ◽

10.21883/os.2019.10.48372.43-19 ◽

2019 ◽

Vol 127 (10) ◽

pp. 654

Author(s):

А.Б. Петрин

Keyword(s):

Light Beam ◽

Layered Structure ◽

Polarized Light ◽

Incident Beam ◽

Polarization Vector ◽

Theoretical Method ◽

Polarized Beam ◽

Linearly Polarized ◽

Finite Aperture ◽

Plane Light

AbstractA theoretical method for investigating reflection of a finite-aperture plane light beam from a flat-layered structure in the Kretschmann scheme is considered. The developed theory is applied for investigating the Goos–Hänchen effect, which arises upon incidence of a linearly polarized light beam with the polarization vector lying in the plane of incidence ( p -polarized beam) and which is that, upon reflection, the incident beam is divided into two close beams of the same polarization. The accuracy of sensors based on this effect is discussed.

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Broadband and polarization-mediated unidirectional plasmon polaritons launch based on metallic triangle aperture arrays

International Journal of Modern Physics B ◽

10.1142/s0217979221500065 ◽

2020 ◽

pp. 2150006

Author(s):

Cong Chen ◽

Jianxin Xi ◽

Panpan Chen ◽

Wanxia Huang ◽

Kuanguo Li ◽

...

Keyword(s):

Extinction Ratio ◽

Polarized Light ◽

Incident Beam ◽

Unidirectional Transmission ◽

Linearly Polarized ◽

The Right ◽

Aperture Arrays ◽

Difference Time ◽

Plasmon Polaritons ◽

Wide Operating

The application of the subwavelength planar structure to control the propagation direction of surface plasmon polaritons (SPPs) has attracted many interests in recent years. However, the traditional unidirectional transmission devices of SPPs are limited by the low extinction ratio, narrow working band and the incapability of controlling the transmission directions. In this study, a novel SPPs unidirectional transmission device based on metallic aperture arrays of the right triangle (RT) is proposed and demonstrated by numerical simulations (finite-difference time-domain method). The maximum extinction ratio of the unidirectional transmission device can reach upto 33 dB under the irradiation of linearly polarized light, and the device possesses a wide operating band ([Formula: see text] nm) while the extinction ratio is greater than 10 dB. Moreover, the transmission direction of SPPs can be flexibly controlled by tuning the polarization of the incident beam. This broadband, polarization-mediated and high extinction ratio unidirectional transmission device shows great potential in the compact plasmonic devices.

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Instrumentation for detecting channelling radiation in the high-voltage electron microscope

Proceedings, annual meeting, Electron Microscopy Society of America ◽

10.1017/s0424820100075385 ◽

1983 ◽

Vol 41 ◽

pp. 318-319

Author(s):

J. H. Butler ◽

C. J. Humphreys

Keyword(s):

Monochromatic Light ◽

Incident Beam ◽

Laboratory Frame ◽

Relativistic Electrons ◽

Voltage Electron ◽

Dipole Emission ◽

Sinusoidal Oscillations ◽

Pass Through ◽

Incident Beam Energy ◽

Increasing Function

Electromagnetic radiation is emitted when fast (relativistic) electrons pass through crystal targets which are oriented in a preferential (channelling) direction with respect to the incident beam. In the classical sense, the electrons perform sinusoidal oscillations as they propagate through the crystal (as illustrated in Fig. 1 for the case of planar channelling). When viewed in the electron rest frame, this motion, a result of successive Bragg reflections, gives rise to familiar dipole emission. In the laboratory frame, the radiation is seen to be of a higher energy (because of the Doppler shift) and is also compressed into a narrower cone of emission (due to the relativistic “searchlight” effect). The energy and yield of this monochromatic light is a continuously increasing function of the incident beam energy and, for beam energies of 1 MeV and higher, it occurs in the x-ray and γ-ray regions of the spectrum. Consequently, much interest has been expressed in regard to the use of this phenomenon as the basis for fabricating a coherent, tunable radiation source.

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