Ultracompact Slow Surface Plasmon Polaritons Superlattice with Broad Bandwidth and Super-High Normalized Delay-Bandwidth Product

In this paper, we propose an ultracompact low-loss plasmonic superlattice for slow surface plasmon polaritons. The superlattice consists of a two-dimensional metal gap waveguide (Ag-SiO₂-Ag) inserted with thin metal films working as coupled reflectors. Theoretical calculations indicate that the device is working on a broad bandwidth of 37 THz including the two telecom wavelengths of 1,310 and 1,550 nm and with mean group refractive index of 3.5 and mean transmission of 60 %. As the total geometric thickness is only 1.6 μm, the normalized delay-bandwidth product of the superlattice is as high as 0.44. All the theoretical prediction based upon the transfer matrix method is validated by the finite-difference time-domain numerical simulation on surface plasmon polaritons propagating in the superlattice.     

Fano Resonances in Compositional Clusters of Aluminum Nanodisks at the UV Spectrum: a Route to Design Efficient and Precise Biochemical Sensors

In this study, we have investigated the plasmon resonance coupling between proximal compositional Al nanoparticles that are organized in a closely spaced molecular orientation as nanoclusters. Plasmon hybridization model is employed as a theoretical model to study the spectral response of the proposed nanostructures. The optical properties of trimer, heptamer, and octamer clusters based on Al/Al₂O₃ nanodisks are evaluated using finite-difference time-domain (FDTD) model numerically. We have proved that a constructive and weak interference between subradiant dark and superradiant bright modes as the plasmon resonance modes causes the appearance of strong Fano resonances at the spectral response of the heptamer and octamer clusters at the UV spectrum. The effects and results of the structural and chemical modifications in the proposed nanoclusters have been discussed and determined. Finally, illuminating an octamer cluster composed of Al/Al₂O₃ nanoparticles and simultaneous modifications in the refractive index of the dielectric environment lead to dramatic changes in the position and quality of the Fano dip. Plotting a linear figure of merit (FoM) for the proposed octamer and quantifying this parameter for the structure as 7.72, we have verified that the structure has a strong potential to be used in designing precise localized surface plasmon resonance (LSPR) sensors that are able to sense minor environmental perturbations with high accuracy. Proposed clusters composed of Al/Al₂O₃ provide an opportunity to design and fabricate low-cost, high responsivity, tunable, and CMOS-compatible devices and efficient biochemical sensors.     

InGaN/GaN MQW Photoluminescence Enhancement by Localized Surface Plasmon Resonance on Isolated Ag Nanoparticles

Spectroscopic study of photoluminescence (PL) enhancement due to the coupling of the light emitters in InGaN/GaN multiple quantum wells (MQWs) with the localized surface plasmon (LSP) resonance on silver (Ag) nanoparticles (NPs) is performed using the confocal microscopy and scanning near-field optical microscopy (SNOM) techniques. The paper is focused on revealing the emission enhancement due to coupling with a single metal nanoparticle. The enhancement is confirmed by time-resolved study of differential transmission (DT). The enhancement suppression caused by potential fluctuations due to the variations of indium content and quantum well (QW) width is also studied. A strong photoexcitation intensity dependence of the emission enhancement due to spectral runaway of the MQW emission from the resonance as carrier density increases is observed both in spatially integrated spectra and in the vicinity of a single nanoparticle.     

A Polarization Filter Based on Photonic Crystal Fiber with Symmetry Around Gold-Coated Holes

We propose a modified design for a photonic crystal fiber (PCF) polarization filter based on surface plasmon resonance (SPR). The air holes are arrayed in diamond lattices, and the diameter of the holes around the gold-coated holes are different that can separate the refractive index of the x-polarization and y-polarization second order surface plasmon polariton (SPP) modes. The influences of structural parameters of the photonic crystal fiber (PCF) on the filter characteristics are studied using the finite element method (FEM). Great changes have taken place in the results of numerical simulation by changing the thickness of the gold film and air hole diameter. Simulation results show that the resonance wavelength is communication wavelength 1550 mm, the loss of the y-polarization mode is 43,126.7 dB/m. When the length of the fiber is 500 μm, extinction ratio is more than 20 dB at the communication wavelength, and bandwidth achieve to 190 nm. It is an important property of PCF polarization filter in production.     

Modification of a Silver Substrate for Advanced Spectro-Electrochemical Applications of SERR Spectroscopy

A substrate for surface-enhanced resonance Raman spectroscopy (SERRS) in the near-ultraviolet (UV) range is presented, extending the potential window for electrochemical applications. Silver nanoparticles were synthesized exhibiting a localized surface plasmon resonance at the excitation wavelength and adsorbed onto a template-stripped silver substrate, whereby the number of particles per unit area was controlled by the adsorption time. Any attempt to employ spectro-electrochemistry on these surfaces, however, was hampered by the anodic dissolution of silver at potentials higher than 300 mV vs. standard hydrogen electrode (SHE). In order to extend the potential window for electrochemistry and still being able to use the resonance effect from silver nanoparticles, a 5-nm thick gold layer was sputtered on top of the Ag/AgNPs substrate. Cyclic voltammetry measurements of cytochrome c (cc) were carried out showing that the electrochemical behavior of gold can extend the potential range of the composite surface significantly. Furthermore, a potentiostatic titration of cc on this substrate by SERRS demonstrated that the resonance Raman effect of silver nanoparticles with the Soret band of the heme had been maintained in the presence of the gold adlayer. The positions of the plasmon resonances measured by reflection spectroscopy method were confirmed by finite-difference time-domain simulations. Gold is the optimal substrate for electrochemistry, whereas silver is the optimal material for plasmonic applications. Combining both metals gives us a surface with good performance for electrochemical applications as well as an enhancement effect sufficient to study redox-active biomacromolecules such as cc.     

Green synthesis of silver and gold nanoparticles using Zingiber officinale root extract and antibacterial activity of silver nanoparticles against food pathogens

In the present study, we synthesized silver and gold nanoparticles with a particle size of 10–20 nm, using Zingiber officinale root extract as a reducing and capping agent. Chloroauric acid (HAuCl₄) and silver nitrate (AgNO₃) were mixed with Z. officinale root extract for the production of silver (AgNPs) and gold nanoparticles (AuNPs). The surface plasmon absorbance spectra of AgNPs and AuNPs were observed at 436–531 nm, respectively. Optimum nanoparticle production was achieved at pH 8 and 9, 1 mM metal ion, a reaction temperature 50 °C and reaction time of 150–180 min for AgNPs and AuNPs, respectively. An energy-dispersive X-ray spectroscopy (SEM–EDS) study provides proof for the purity of AgNPs and AuNPs. Transmission electron microscopy images show the diameter of well-dispersed AgNPs (10–20 nm) and AuNPs (5–20 nm). The nanocrystalline phase of Ag and Au with FCC crystal structures have been confirmed by X-ray diffraction analysis. Fourier transform infrared spectroscopy analysis shows the respective peaks for the potential biomolecules in the ginger rhizome extract, which are responsible for the reduction in metal ions and synthesized AgNPs and AuNPs. In addition, the synthesized AgNPs showed a moderate antibacterial activity against bacterial food pathogens.     

A bibliometric investigation of life cycle assessment research in the web of science databases

Purpose

Over the past few decades, life cycle assessment (LCA) methodologies have been developed extensively, and there has been a growing interest in LCA research. However, as attested by scientific literature, few systematic, synthesizing, and visualizing studies have been found on LCA research which show how this field has evolved over time. The goal of this mainly bibliometric, empirical study is to get insight into publication performance of global LCA research, characterize its intellectual structure, and trace its evolution by using the bibliometric method with visual mapping.

Methods

Based on the data from the ISI Web of Science databases Science Citation Index Expanded (SCI-EXPANDED), Social Sciences Citation Index (SSCI), Conference Proceedings Citation Index—Science (CPCI-S) and Conference Proceedings Citation Index —Social Science & Humanities (CPCI-SSH) in the period of 1998–2013, bibliometric methods are used to investigate general development profiles of LCA research, while knowledge domain visualization technologies are employed to conduct a further co-citation analysis.

Results and discussion

The results and discussions of this research mainly shed light on (1) basic statistics of significant publication performances, (2) research focuses and their intellectual base in LCA research, (3) how the streams of research evolved during the whole period of interest.

Conclusions

A new work on systematic and synthesizing study is conducted in this research to evaluate and map LCA research-related context. Some salient scholarly journals and institutions are identified that have shown a significant impact during the exponential growth of LCA research in the past 16 years. Biofuel, process design, solid waste management, and livestock production-related LCA researches are the main areas where interest is surging, confirmed by the active citers in each specialty. Furthermore, from the perspective of science mapping, evolution of LCA research is traced and some pivot publications are identified, which work as structural holes for the LCA-research development in the given time window.     

Application of AAO Matrix in Aligned Gold Nanorod Array Substrates for Surface-Enhanced Fluorescence and Raman Scattering

In this paper, we probed surface-enhanced Raman scattering (SERS) and surface-enhanced fluorescence (SEF) from probe molecule Rhodamine 6G (R6G) on self-standing Au nanorod array substrates made using a combination of anodization and potentiostatic electrodeposition. The initial substrates were embedded within a porous alumina template (AAO). By controlling the thickness of the AAO matrix, SEF and SERS were observed exhibiting an inverse relationship. SERS and SEF showed a non-linear response to the removal of AAO matrix due to an inhomogeneous plasmon activity across the nanorod which was supported by FDTD calculations. We showed that by optimizing the level of AAO thickness, we could obtain either maximized SERS, SEF or simultaneously observe both SERS and SEF together.     

Systematic Theoretical Analysis of Selective-Mode Plasmonic Filter Based on Aperture-Side-Coupled Slot Cavity

By taking the aperture as a resonator, we propose an analytical model to describe the dynamic transmission in metal-dielectric-metal (MDM) waveguide aperture-side-coupled with slot cavity. The theoretical results and the finite-difference time-domain (FDTD) simulations agree well with each other, and both demonstrate the mode selectivity and filtering tunability of the plasmonic structure. By adjusting the phase shifts in slot cavity or resonance frequency determined by the aperture, one can realize the required transmission spectra and slow light effect. The theoretical analysis may open up avenues for the control of light in highly integrated optical circuits.     

Antibacterial activity of silver nanoparticle-coated fabric and leather against odor and skin infection causing bacteria

We present a simple, eco-friendly synthesis of silver and gold nanoparticles using a natural polymer pine gum solution as the reducing and capping agent. The pine gum solution was combined with silver nitrate (AgNO₃) or a chloroauric acid (HAuCl₄) solution to produce silver nanoparticles (AgNPs) and gold nanoparticles (AuNPs), respectively. The reaction process was simple; formation of the nanoparticles was achieved by autoclaving the silver and gold ions with the pine gum. UV–Vis spectra showed surface plasmon resonance (SPR) for silver and gold nanoparticles at 432 and 539 nm, respectively. The elemental forms of AgNPs and AuNPs were confirmed by energy-dispersive X-ray spectroscopy (EDX). Fourier transform infrared spectroscopy (FTIR) showed the biomolecules present in the pine gum, AgNPs, and AuNPs. Transmission electron microscopy (TEM) images showed the shape and size of AgNPs and AuNPs. The crystalline nature of synthesized AgNPs and AuNPs was confirmed by X-ray crystallography [X-ray diffraction (XRD)]. Application of synthesized AgNPs onto cotton fabrics and leather, in order to evaluate their antibacterial properties against odor- or skin infection-causing bacteria, is also discussed. Among the four tested bacteria, AgNP-coated cotton fabric and leather samples displayed excellent antibacterial activity against Brevibacterium linens.     

Analysis of γ-Aminobutyric Acid (GABA) Type A Receptor Subtypes Using Isosteric and Allosteric Ligands

The GABA_A receptors (GABA_ARs) play an important role in inhibitory transmission in the brain. The GABA_ARs could be identified using a medicinal chemistry approach to characterize with a series of chemical structural analogues, some identified in nature, some synthesized, to control the structural conformational rigidity/flexibility so as to define the ‘receptor-specific’ GABA agonist ligand structure. In addition to the isosteric site ligands, these ligand-gated chloride ion channel proteins exhibited modulation by several chemotypes of allosteric ligands, that help define structure and function. The channel blocker picrotoxin identified a noncompetitive channel blocker site in GABA_ARs. This ligand site is located in the transmembrane channel pore, whereas the GABA agonist site is in the extracellular domain at subunit interfaces, a site useful for low energy coupled conformational changes of the functional channel domain. Also in the trans-membrane domain are allosteric modulatory ligand sites, mostly positive, for diverse chemotypes with general anesthetic efficacy, namely, the volatile and intravenous agents: barbiturates, etomidate, propofol, long-chain alcohols, and neurosteroids. The last are apparent endogenous positive allosteric modulators of GABA_ARs. These binding sites depend on the GABA_AR heteropentameric subunit composition, i.e., subtypes. Two classes of pharmacologically very important allosteric modulatory ligand binding site reside in the extracellular domain at modified agonist sites at other subunit interfaces: the benzodiazepine site, and the low-dose ethanol site. The benzodiazepine site is specific for certain subunit combination subtypes, mainly synaptically localized. In contrast, the low-dose (high affinity) ethanol site(s) is found at a modified benzodiazepine site on different, extrasynaptic, subtypes.     

Numerical study of nanoparticle sensors based on the detection of the two-photon-induced luminescence of gold nanorod antennas

We investigate numerically the modification of the nonlinear optical properties of a nanoantenna in the trapping of nanoparticles (NPs) by using both the discrete dipole approximation method and the finite-difference time-domain technique. The nanoantenna, which is formed by two gold nanorods (GNRs) aligned end to end and separated by a small gap, can emit strong two-photon-induced luminescence (TPL) under the excitation of a femtosecond laser light which is resonant with its longitudinal surface plasmon resonance. In addition, the excited antenna can stably trap small NPs which in turn induce modifications in the emitted TPL. These two features make it a promising candidate for building highly sensitive detectors for NPs of different materials and sizes. It is demonstrated that sensors built with antennas possess higher sensitivities than those built with single GNRs and nanorod-based antennas are more sensitive than nanoprism-based antennas. In addition, it is found that the trapping probability for a second NP is significantly reduced for the antenna with a trapped NP, implying that trapping of NPs may occur sequentially. A relationship between the TPL of the system (antenna?+?NP) and the optical potential energy of the NP is established, enabling the extraction of the information on the optical potential energy and optical force by recording the TPL of the system. It is shown that the sequential trapping and releasing of NPs flowing in a microfluid channel can be realized by designing two different antennas arranged closely.     

Optically Stimulated Luminescence Under Plasmon Resonance Conditions Enhances X-Ray Detection

Plasmon enhancement of luminescence close to noble metal nanoparticles is a powerful tool for many optical purposes. Although the plasmon properties of noble metal nanoparticles found application in many different areas, no reports on their use to detect ionizing radiation exist. Here, we investigate the use of the localized surface plasmon resonance of noble metal nanoparticles, to obtain plasmon-enhanced optically stimulated luminescence (OSL). The OSL intensity depends on particle size: we observed enhanced OSL in samples containing silver nanoparticles and quenched OSL in samples bearing silver microparticles. The local field close to the nanoparticles surface under surface plasmon resonance condition increased the excitation rate of the X-ray-generated F centers, enhancing luminescence. Moreover, noble metal nanoparticles can also concentrate luminescent centers close to their surface, leading to a synergistic effect that facilitates detection and intensify OSL. These promising findings may give rise to a new class of ionizing radiation detectors. Figure

OSL intensity dependence on concentration of nanoparticles and microparticles of a NaCl/Ag composite. For nanoparticles, there is a sustained enhancement with mass content.     

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).     

Molecular targets in the search for endothelium-protecting compounds

Impairment of endothelial function forms basis for many cardiovascular diseases, therefore today it becomes an independent target for therapeutic action, and the search for new compounds possessing endothelium-protective properties is one of the prospective goals of the pharmacotherapy and medicinal chemistry. An efficient instrument to solve the problem is the use of methods of molecular modeling. Application of the methods is possible only if detailed information on three-dimensional structure and function of molecular targets—receptors and enzymes responsible for signal transduction both inside and outside endothelial cells—is available. In the review we collected the data on the structure and functions of various macromolecules involved in the process of regulation of vascular tone. The structure of endothelial NO-synthase (EC 1.14.13.39) (eNOS) responsible for synthesis of nitrogen oxide and involved in the process of vascular tone regulation is described. The importance of its substrate, L-arginine, from the point of view of eNOS activity regulation is emphasized; the data on structure and functions of L-arginine transport system are presented. Also, various pathways of eNOS activity regulation are described, including activation and competitive inhibition through binding of exogenous substances in its active center and inhibition through caveolin binding at eNOS oxygenase domain among them, as well as regulation by means of phosphorylation of individual eNOS amino acid residues by protein kinases and their dephosphorylation by phosphatases. The importance of membrane receptors of endotheliocytes as targets for substances possessing endothelium-protective activity is emphasized. Receptors of endothelin, thrombocyte activation factor, prostaglandins, bradykinin, histamine, serotonin, and protein kinase-activated receptors are among them. The importance of calcium and potassium ion channels in vessel cells for endothelium protection is emphasized. Finally, the macromolecules discussed in the review are considered as targets in the search for endothelium-protective therapeutic agents by the proposed approaches and methods of molecular modeling.     

A Pilot Study on the Contribution of Folate Gene Variants in the Cognitive Function of ADHD Probands

Genetic abnormalities in components important for the folate cycle confer risk for various disorders since adequate folate turnover is necessary for normal methylation, gene expression and chromosome structure. However, the system has rarely been studied in children diagnosed with attention deficit hyperactivity disorder (ADHD). We hypothesized that ADHD related cognitive deficit could be attributed to abnormalities in the folate cycle and explored functional single nucleotide polymorphisms in methylenetetrahydrofolate dehydrogenase (rs2236225), reduced folate carrier (rs1051266), and methylenetetrahydrofolate reductase (rs1801131 and rs1801133) in families with ADHD probands (N = 185) and ethnically matched controls (N = 216) recruited following the DSM-IV. After obtaining informed written consent for participation, peripheral blood was collected for genomic DNA isolation and PCR-based analysis of target sites. Data obtained was analyzed by UNPHASED. Interaction between sites was analyzed by the multi dimensionality reduction (MDR) program. Genotypic frequencies of the Indian population were strikingly different from other ethnic groups. rs1801133 “T” allele showed biased transmission in female probands (p < 0.05). Significant difference in genotypic frequencies for female probands was also noticed. rs1801131 and rs1801133 showed an association with low intelligence quotient (IQ). MDR analysis exhibited independent effects and contribution of these sites to IQ, thus indicating a role of these genes in ADHD related cognitive deficit.     

Surfactant-assisted bio-conjugated synthesis of silver nanoparticles (AgNPs)

A simple one-spot synthetic route for the production of Ag-nanoparticles using aqueous extract of citrus lemon is being reported in presence of shape-directing cetyltrimethylammonium bromide (CTAB). To our knowledge, this is the first report where the biomolecules form a layer around a group of the Ag-nanoparticles in which the inner layer is bound to the AgNPs surface via the hydroxyl groups of citric acid. The appearance of a sharp surface plasmon resonance band in the UV–visible region might be due to the formation of spherical Ag-nanoparticles. Agglomeration number (N _Ag), the average number of silver atoms per nanoparticle (N), molar concentrations of nanoparticle (C) in solution, extinction coefficient (ε) and increase in the Fermi energy (ΔE _F) were calculated using Mie theory and discussed. Interestingly, reaction mixture became turbid at higher [CTAB] due to the uncontrolled growth of Ag-nanoparticles. The transmission electron microscopic images of nanoparticles, recorded at different magnifications.     

Graphiolales: Basidiomycetes parasitic on palms

Graphiola phoenicis was restudied by light microscopy and investigated in detail with the scanning and the transmission electron microscopes. Hyphae of the fruitbody are mainly dikaryotic. Karyogamy occurs in cells which are interpreted as meiosporangia (basidia), and which develop in chains. Shortly after karyogamy, meiosis takes place in these basidia. Primary, sessile meiospores are then formed which later divide and produce thick-walled diaspores. The latter germinate either by hyphae or by yeast-like budding. The nutritional requirements of pure cultures of the yeast stage were also investigated. Life cycle, karyological criteria, ultrastructural details, and chemical tests clearly show thatGraphiola belongs in theBasidiomycetes. The taxonomic position within theHeterobasidiomycetes is discussed and the orderGraphiolales is validated.     

Plasmonic Property and Stability of Core-Shell Au@SiO2 Nanostructures

Au nanorod (Au NR) is one of the most studied colloidal nanostructures for its tunable longitudinal surface plasmon resonance (SPR_L) property in the near infrared region. And surface coating Au NRs into core-shell nanostructures is particularly important for further investigation and possible applications. In this paper, Au NRs colloids were synthesized using an improved seed method. Then as-prepared Au NRs were coated with SiO₂ to form a core-shell nanostructure (Au@SiO₂) with different shell thickness. And the influence of SiO₂ shell on the SPR_L of Au NRs was investigated based on the experimental results and FDTD simulations. Under the 808 nm laser irradiating, the stability of Au@SiO₂ was studied. Compared with Au NRs, the Au@SiO₂ is stable with increasing laser power (up to 8 W), whereas Au NRs undergo a shape deformation from rod to spherical nanoparticle when the laser power is 5 W. The high stability and tunable optical properties of core-shell structured Au@SiO₂, along with advantages of SiO₂, show that Au@SiO₂ composites are promising in designing plasmonic photothermal properties or further applications in nanomedicine.