Cascade Electric Field Enhancement in the Orthogonal-Nanorod Structures

The transverse mode electron oscillations contribute to most of the surface-enhanced Raman scattering (SERS) intensity from the nanorod array substrates. To enhance the transverse mode electron oscillation and improve the SERS enhancements, the local electric field distribution of the orthogonal-nanorod structures, composed of two parallel horizontal nanorods in between two parallel vertical nanorods, has been studied. The local electric fields of the longitudinal mode along the horizontal nanorods act as the excitation for the transverse mode electron oscillations in vertical nanorods, leading to the cascade enhancements of the electric fields around the vertical nanorods. In addition, the plasmon peaks of the longitudinal modes can be tuned by changing the lengths and the widths of the horizontal nanorods and the separations between horizontal and vertical nanorods. These results would be much helpful to engineer SERS substrates to obtain larger SERS enhancements.     

Experimental Demonstration of Spoof Surface Plasmon Based THz Antennas for Huge Electric Field Enhancement

Plasmonics - We experimentally demonstrate the fabrication and optical measurement of a novel terahertz antenna array due to the excitation of spoof surface plasmon modes. With the unit cell...     

Improve the Local Electric Field Enhancement of Au Cylindrical Nanohole by Pt Coating

Plasmonics - Local electric field enhancement in a long cylindrical Au nanohole with Pt coating has been theoretically studied based on quasi-static model. Calculation results show that both the...     

Selection and Identification of a Listeria monocytogenes Target Strain for Pulsed Electric Field Process Optimization

Nine Listeria monocytogenes strains were treated individually with a continuous pulsed electric field (PEF) apparatus, and their sensitivities to the treatment were compared at 25 kV/cm. When cell suspensions of these strains in 0.1% NaCl (pH 7.0) were treated at 23°C for 144 μs, inactivation ranged from 0.7 to 3.7 log₁₀ CFU/ml. Inactivation by 72-μs PEF treatments at 37°C ranged from 0.3 to 2.5 log₁₀ CFU/ml. L. monocytogenes OSY-8578 was substantially more resistant than other strains when cells were PEF treated in 0.1% NaCl, whereas Scott A was one of the most sensitive strains. The superiority of OSY-8578's resistance to that of Scott A was confirmed in 50% diluted acid whey (pH 4.2). Changes in sensitivity to PEF during phases of growth were minimal in OSY-8578 and substantial in Scott A. Use of L. monocytogenes OSY-8578, therefore, is recommended in studies to optimize PEF processes that target L. monocytogenes. The nine L. monocytogenes strains were genotyped with pulsed-field gel electrophoresis (PFGE) and arbitrarily primed PCR (AP-PCR) techniques. These strains were better differentiated with PFGE than with AP-PCR. The target strain (OSY-8578) was characterized by both molecular typing techniques, but resistance to PEF, in general, was not associated with a particular genotype group.     

A Computational Study of the Giant Local Electric Field Enhancement in Al-Au-Ag Trimetallic Three-Layered Nanoshells

The surface plasmon resonance (SPR)-induced local field effect in Al-Au-Ag trimetallic three-layered nanoshells has been studied theoretically. Because of having three kinds of metal, three plasmonic bands have been observed in the absorption spectra and the local electric field factor spectra. The local electric field enhancement and the corresponding resonance wavelength for different plasmon coupling modes and spatial positions of the Al-Au-Ag nanoshells with various geometry dimensions are investigated to find the maximum local electric field enhancement. The calculation results indicate that the giant local electric field enhancement could be stimulated by the plasmon coupling in the middle Au shell or the outer Ag shell and could be optimized by increasing the Ag shell thickness and decreasing the Au shell thickness. What is more, the local electric field enhancement also nonmonotonously depends on the dielectric constant of the environment; the local electric field intensity will be weakened when the surrounding dielectric constant is too small or too large.

     

Theoretical Localized Electric Field Enhancement in Tip-Enhanced Spectroscopy Using Multi-Order Radially Polarized Modes

Multi-order radially polarized modes (RPMs), including Bessel-Gaussian, Gaussian, Super Gaussian, and multi-order hollow Gaussian are respectively utilized as the illumination laser to achieve tip-enhanced spectroscopy (TES). Based on the vector diffraction theory and finite difference time domain (FDTD) analysis, we achieve the optimization of RPM illuminated TES system, including the focal spot size, focal depth, and electric field enhancement factor, in which the focal spot size of 5th order hollow Gaussian RPM is smallest (0.54λ) and the focusing depth of super Gaussian RPM is longest (4.71λ). Specially, it is found that the multi-order hollow Gaussian RPM illuminated TES system with the tip cone angle of 45^° reveals better focusing ability and 40~60-fold electric field enhancement factor compared to the linearly polarized mode (LPM) illuminated TES system. These results will supply a useful reference for spectral signal enhancement of TES system.     

A Conjugate Gradient Algorithm with a Trust Region for Molecular Geometry Optimization

An algorithm is presented for the optimization of molecular geometries and general nonquadratic functions using the nonlinear conjugate gradient method with a restricted step and restart procedure. The algorithm only requires the evaluation of the energy function and its gradient, therefor less memory storage is needed than for other conjugate gradient algorithms. Some numerical results are also presented and the efficiency and behaviour of the algorithm is compared with the standard conjugate gradient method. We also present comparisons of both conjugate gradient and variable metric methods with and without the trust region technique. One of the main conclusions of the present work is that a trust region always improves the converge of any optimization method. A sketch of the algorithm is also given.     

Surface Plasmon as a Probe of Local Field Enhancement

New method of experimental determination of local field enhancement at metal nanoparticles is suggested. It uses surface plasmon as a probe. Alternating-sign shift of surface plasmon resonance in copper nanoparticles incorporated in silica matrix has been observed under irradiation by intense femtosecond laser pulse. The red shift of plasmon observed during the action of pump pulse is interpreted as a result of change of dielectric constant of silica matrix due to optical Kerr effect in electric field of pump pulse enhanced in a vicinity of metal nanoparticles. The field enhancement factor is estimated from the value of the observed red shift of plasmon resonance.     

Field Enhancement by Shaping Nanocavities in a Gold Film

We report on 2D plasmonic crystals composed of a hexagonal lattice of polymeric nanopillars embedded in an optically thick gold film on a glass substrate. A tapered shape of the polymeric pillars is proved to localize the electric field distribution close to the free surface of the device and to determine a significant increase in the electric field intensity particularly when the incident light comes from the glass side. These effects significantly improve the sample sensitivity to a refractive index change occurring at the free surface of the device.     

Optimization of Nanoparticle Size for Plasmonic Enhancement of Fluorescence

This paper reports on the enhancement of fluorescence that can result from the proximity of fluorophores to metallic nanoparticles (NPs). This plasmonic enhancement, which is a result of the localized surface plasmon resonance at the metal surface, can be exploited to improve the signal obtained from optical biochips and thereby lower the limits of detection. There are two distinct enhancement effects: an increase in the excitation of the fluorophore and an increase in its quantum efficiency. This study focuses on the first of these effects where the maximum enhancement occurs when the NP plasmon resonance wavelength coincides with the fluorophore absorption band. In this case, the excitation enhancement is proportional to the square of the amplitude of the electric field. The scale of the enhancement depends on many parameters, such as NP size and shape, metal type, and NP–fluorophore separation. A model system consisting of spherical gold/silver alloy NPs, surrounded by a silica spacer shell, to which is attached a fluorescent ruthenium dye, was chosen and the dependence of the fluorescence enhancement on NP diameter was investigated. Theoretical calculations, based on Mie theory, were carried out to predict the maximum possible enhancement factor for spherical NPs with a fixed composition and a range of diameters. Spherical NPs of the same composition were fabricated by chemical preparation techniques. The NPs were coated with a thin silica shell to overcome quenching effects and the dye was attached to the shell.     

Field Enhancement of Tip with Spiral Nanostructure

Recently, tips suitable for illuminating from top to bottom have received great attraction due to high energy utilization and easiness of constituting array, which can increase scan efficiency to realize large-area rapid microprobe scan. In this work, we study the field enhancement on a cone tip with a planar Archimedes’ spiral nanostructure under an illumination of circularly polarized light. By means of a simulation based on phase matching theory and finite-difference time-domain, it is demonstrated that electric field intensity in close proximity to the tip, which is contributed by evanescent mode (EM) and propagating mode (PM) of surface plasmon polaritons (SPPs) induced from Archimedes’ spiral slits, increases 3 orders of magnitude than that of the incoming beam. The beam induced by the tip has a full width at half maximum of 10 nm (~0.015λ₀).     

Optimization of Non-Nutritional Factors for a Cost-Effective Enhancement of Nisin Production Using Orthogonal Array Method

In order to increase nisin production in a cost-effective manner, non-nutritional factors as well as nutritional parameters must be optimized. In this study, optimization of the most important non-nutritional factors for nisin production using orthogonal array method was performed. Optimization of temperature, agitation, age and size of inoculum, medium initial pH value and flask volume/medium volume ratio in de Man, Rogosa and Sharpe (MRS) medium in batch fermentation was accomplished. Nisin was produced by Lactococcus lactis subsp. lactis PTCC 1336 and measured by bioassay method using Micrococcus luteus PTCC 1169 as the nisin-sensitive strain. The optimum levels of non-nutritional factors for maximum nisin production and productivity were obtained as: flask volume/medium volume ratio: 5.00, medium initial pH value: 8.00, inoculum size: 1%, inoculum age: 24 h old (A = 1.7), agitation: 100 rpm and temperature: 27 °C. Under the optimized conditions, maximum nisin production and maximum nisin productivity were 599.70 IU/mL and 37.48 IU/mL/h, respectively.     

Enhancement of Glutaraldehyde Biocidal Efficacy by the Application of an Electric Field. Effect on Sessile Cells and on Cells Released by the Biofilm

Summary The aim of this paper was to evaluate the possible enhancement of the biocidal efficacy of glutaraldehyde against Pseudomonas fluorescens biofilms by the application of an electric field. The behaviour of sessile cells and cells released by the biofilms was assed. Biofilms were formed on thin stainless steel coupons immersed in culture media inoculated with Pseudomonas fluorescens. Treatments using glutaraldehyde (TGA) and both glutaraldehyde and electric field application (TGAEF) were carried out with the samples with biofilms. TGA: samples with biofilms were immersed in glass cells containing a buffer solution with different glutaraldehyde concentrations in the 25–500 ppm range. TGAEF: samples with biofilms were immersed in an electrochemical cell containing glutaraldehyde solution where a direct electric current (4 × 10⁻⁴ A cm⁻²) was delivered to the chamber. The evolution of biofilms was observed through optical microscopy at real time. Results show that the electric field enhanced glutaraldehyde efficacy reducing the number of surviving cells in the range of one to four orders with respect to those with TGA treatment. The sensitivity of the cells to the treatments decreased in the following order: planktonic cells > cells released by the biofilm > sessile cells.     

Electron Swarm Parameters in Helium in a Strong Electric Field

Plasma Physics Reports - Dependences of kinetic and transport coefficients of electrons in helium on the electric field strength E reduced to the atomic concentration N in the E/N range from 15 to...     

Electric Field Encephalography as a Tool for Functional Brain Research: A Modeling Study

We introduce the notion of Electric Field Encephalography (EFEG) based on measuring electric fields of the brain and demonstrate, using computer modeling, that given the appropriate electric field sensors this technique may have significant advantages over the current EEG technique. Unlike EEG, EFEG can be used to measure brain activity in a contactless and reference-free manner at significant distances from the head surface. Principal component analysis using simulated cortical sources demonstrated that electric field sensors positioned 3 cm away from the scalp and characterized by the same signal-to-noise ratio as EEG sensors provided the same number of uncorrelated signals as scalp EEG. When positioned on the scalp, EFEG sensors provided 2–3 times more uncorrelated signals. This significant increase in the number of uncorrelated signals can be used for more accurate assessment of brain states for non-invasive brain-computer interfaces and neurofeedback applications. It also may lead to major improvements in source localization precision. Source localization simulations for the spherical and Boundary Element Method (BEM) head models demonstrated that the localization errors are reduced two-fold when using electric fields instead of electric potentials. We have identified several techniques that could be adapted for the measurement of the electric field vector required for EFEG and anticipate that this study will stimulate new experimental approaches to utilize this new tool for functional brain research.     

The Effects of a Low-Frequency Electric Field on Recombinant Luciferase Activity

Biophysics - Studies on the effects of an electromagnetic field on the activity of recombinant luciferase in the luciferase–luciferin–ATP-Mg2+ system were conducted. The enzymatic...     

Long Term Measurement of the Trans-Root Electric Potential in a Persimmon Tree in the Field

kaki tree (Diospyros kaki, Japanese persimmon), which showed clear diurnal oscillation throughout two successive years. The level of the TRP on the average for every ten days had two minima (ca. –70 mV) in mid winter and mid summer, and two maxima (ca. –30 mV) in October and May. A regular seasonal change in the amplitude of the oscillation was observed; it was at its maximum (ca. 70 mV) in early spring just before the sprouting of new leaves, and at its minimum (ca. 10 mV) during summer and early autumn when leaves were fully expanded. The relationship between the TRP, water transport and rainfall is discussed. Received 18 February 1998/ Accepted in revised form 8 November 1998     

Convolutional Virtual Electric Field for Image Segmentation Using Active Contours

Gradient vector flow (GVF) is an effective external force for active contours; however, it suffers from heavy computation load. The virtual electric field (VEF) model, which can be implemented in real time using fast Fourier transform (FFT), has been proposed later as a remedy for the GVF model. In this work, we present an extension of the VEF model, which is referred to as CONvolutional Virtual Electric Field, CONVEF for short. This proposed CONVEF model takes the VEF model as a convolution operation and employs a modified distance in the convolution kernel. The CONVEF model is also closely related to the vector field convolution (VFC) model. Compared with the GVF, VEF and VFC models, the CONVEF model possesses not only some desirable properties of these models, such as enlarged capture range, u-shape concavity convergence, subject contour convergence and initialization insensitivity, but also some other interesting properties such as G-shape concavity convergence, neighboring objects separation, and noise suppression and simultaneously weak edge preserving. Meanwhile, the CONVEF model can also be implemented in real-time by using FFT. Experimental results illustrate these advantages of the CONVEF model on both synthetic and natural images.     

Transmission Control Property of a Nano-optical System Made by an Antenna over a Bowtie Aperture

In this paper, we report a characteristic transmission control property of a nano-optical system by introducing an antenna over the input opening of a bowtie aperture. The transmission process through the system is investigated quantitatively by the coupling and transmission efficiencies, and an optical switch effect is found as the antenna length varies. To understand the physical mechanism, we then investigate the electrical field distribution of the antenna over a rectangle aperture as a simplified model. It is discovered that the "on" state of the system is due to Fabry–Perot resonances in the horizontal cavity formed by antenna, dielectric layer, and metal film. On the other hand, a cutoff occurs for the characteristic rectangle length shorter than the diffraction limit to turn the device to the "off" state. Such a phenomenon can thus provide a promising candidate for application in manipulating light in large-scale optoelectronic device integration.     

时域相干刺激研究进展

脑深部电刺激已成为许多神经和精神疾病的有效治疗方法。然而,侵入性的电极植入会带来手术并发症的风险,并且刺激靶区在植入后很难改变。经颅磁刺激和经颅电刺激等非侵入性刺激方法为调节大脑功能提供了新的途径。但是,尚未证明这些非侵入性脑刺激方法可以直接调节脑深部神经元活动而不影响皮层神经元。因此,这些方法主要用于调节大脑表层脑区的神经活动。时域相干（temporal interference,TI）刺激是通过两个高频电场相互作用,产生低频包络调节神经活动的一种非侵入式脑深部电刺激的新方法,该方法有望解决无创脑深部刺激的需求。本文首先介绍TI刺激的概念以及安全性,然后阐述TI刺激现有研究中的电场分析方法,并讨论电场分析相关的生理模型建模方法和仿真平台以及TI刺激诱发场分布的研究进展与在动物和人体中的应用进展。最后,本文展望了TI刺激技术未来发展方向,以期为无创脑深部刺激研究提供新的研究思路。