Your search keyword '"Barkay, Z."' showing total 185 results

51. On the origin of hole formation in YBCO films

Author

Krupke, R., primary, Barkay, Z., additional, and Deutscher, G., additional

Published

1997

52. Evaluation of the minority carrier diffusion length by means of electron beam induced current and Monte Carlo simulation in AlGaAs and GaAs p-i-n solar cells

Author

Grunbaum, E, primary, Napchan, E, additional, Barkay, Z, additional, Barnham, K, additional, Nelson, J, additional, Foxon, C T, additional, Roberts, J S, additional, and Holt, D B, additional

Published

1995

53. Development and Characterizationof Composite YSZ–PEIElectrophoretically Deposited Membrane for Li-Ion Battery.

Author

Hadar, R., Golodnitsky, D., Mazor, H., Ripenbein, T., Ardel, G., Barkay, Z., Gladkich, A., and Peled, E.

Published

2013

54. Study of cathodoluminescence in high Tc superconductors

Author

Barkay, Z., primary, Racah, D., additional, Hass, N., additional, Dwir, B., additional, Grünbaum, E., additional, and Deutscher, G., additional

Published

1993

55. Spectral cathodoluminescence of impurity phases in Y1Ba2Cu3O7−δsuperconductors

Author

Barkay, Z., primary, Deutscher, G., additional, Grunbaum, E., additional, and Dwir, B., additional

Published

1992

56. Preparation and analysis of a two-components breath figure at the nanoscale.

Author

Kofman, R., Allione, M., Celestini, F., Barkay, Z., and Lereah, Y.

Subjects

PHYSICS, PARTICLES, NANOCRYSTALS, TRANSMISSION electron microscopy, ELECTRON microscopy

Abstract

Solid/liquid two-components Ga–Pb structures in isolated nanometer sized particles have been produced and studied by electron microscopy. Production is based on the breath figure technique and we investigate the way the two components are distributed. We clearly identify two growth regimes associated with the two different ways a Pb atom incorporates into a Ga nanodrop. Using TEM and SEM, the shape and microstructure of the nanoparticles are studied and the results obtained are in good agreement with the proposed model. The experimental technique used appears to be appropriate to produce Pb nanocrystals in liquid Ga nano-containers. [ABSTRACT FROM AUTHOR]

Published

2009

57. Cathodoluminescence in sem of bulk and thin films of high Tc superconductors

Author

Barkay, Z., primary, Racah, D., additional, Lereah, Y., additional, Deutscher, G., additional, and Grünbaum, E., additional

Published

1991

58. Cathodoluminescence study of thin films of highTcsuperconductors

Author

Barkay, Z., primary, Azoulay, J., additional, Lereah, Y., additional, Dai, U., additional, Hess, N., additional, Racah, D., additional, Grünbaum, E., additional, and Deutscher, G., additional

Published

1990

59. Patterning of high Tc superconducting thin films by copper-vapour laser.

Author

Barkay, Z., Deutscher, G., Kagan, Y., and Shapira, Y.

Abstract

The projection microscope, based on a copper-vapour laser (CVL), is a unique system which combines the capabilities of a high magnification optical microscope and the performance of a high quality laser. The system performance with respect to high Tc superconducting (HTSC) device technology was studied using a scanning electron microscope. CVL patterning of YBaCuO films was demonstrated down to less than 2 μm. The thin films could be partially etched in depth just by controlling the laser pulse power density. In addition in HTSC device applications it could remove layers from thin films up to a complete etching. [ABSTRACT FROM AUTHOR]

Published

1998

60. Ultrathin Gold Island Films on Silanized Glass. Morphology and Optical Properties

Author

Doron-Mor, I., Barkay, Z., Filip-Granit, N., Vaskevich, A., and Rubinstein, I.

Abstract

Evaporated gold island films have been the subject of studies dealing with a variety of spectroscopic and sensing applications. Development of these and other applications requires film stability as well as tunability of the morphology and optical properties of the island films. In the present work, ultrathin, island-type gold films were prepared by evaporation of 1.0−15.0 nm (nominal thickness) gold at a rate of 0.005−0.012 nm s^-1 onto glass substrates modified with 3-mercaptopropyl trimethoxysilane (MPTS), the latter used to improve the Au adhesion to the glass. The morphology of the films, either unannealed or annealed (20 h at 200 °C), was studied using atomic force microscopy (AFM) and high-resolution scanning electron microscopy (HR-SEM). The information provided by the two imaging techniques is complementary, giving a good estimate of the shape of the islands and its variation with film thickness and annealing. The optical properties of the films were examined using transmission UV−vis spectroscopy, showing a strong dependence of the localized Au surface plasmon (SP) band on the morphology of the island films. The imaging and spectroscopy indicate a gradual transition from isolated islands to a continuous film upon increasing the Au thickness.

Published

2004

61. Electrical charging of percolating samples in the scanning electron microscope.

Author

Barkay, Z., Dwir, B., Deutscher, G., and Grünbaum, E.

Subjects

*INDIUM, *SCANNING electron microscopy

Abstract

Electrical properties of indium percolating samples were investigated by the charging effect in the scanning electron microscope. The finite clusters and the infinite cluster were identified due to the difference in their charging images. The finite clusters exhibited a capacitor-like behavior. An electric breakdown in a tree-like structure was obtained in the indium insulating films. [ABSTRACT FROM AUTHOR]

Published

1989

62. High-resolution scanning electron microscopy of dopants in p-i-n junctions with quantum wells

Author

Barkay, Z., Grunbaum, E., Shapira, Y., Wilshaw, P., Barnham, K., Bushnell, B., Ekins-Daukes, N. J., and MASSIMO MAZZER

Subjects

Condensed Matter::Materials Science

Abstract

We have studied the electric field distribution in p-i-n structures with multi-quantum wells (MQW) using the method of dopant (ionization potential) contrast in high resolution (with a cold field emission electron gun) scanning electron microscopy (HRSEM). The samples are GaAs-based ternary compound layer structures used for high-efficiency solar cells, consisting of p-i-n junctions, in which various numbers of InGaAs quantum wells have been inserted into the intrinsic (undoped) region. The results show an increasing secondary electron signal across the n, i and p regions while the series of 8 nm wide quantum wells and their corresponding barriers within the i-region are clearly distinguished. The field distribution is obtained by differentiating the dopant contrast curves. This study highlights the capability of HRSEM to provide information on active doping and associated electric fields within electronic nanostructures.

63. Silicon micro-spheres in microwave-excited ball-lightning-like plasmoids

Author

Eli Jerby, Meshcheryakov, O., Ashkenazi, D., Barkay, Z., Eliaz, N., Mitchell, J. B. A., Narayanan, T., Legarrec, J. L., Sztucki, M., and Wonde, S.

64. Investigation of the electrical conduction of thin metal films by scanning electron microscopy

Author

Barkay, Z., primary, Dwir, B., additional, and Deutscher, G., additional

Published

1989

65. The dependence of filtered vacuum arc deposited ZnO–SnO2 thin films characteristics on substrate temperature.

Author

Çetinórgü, E., Goldsmith, S., Barkay, Z., and Boxman, R. L.

Abstract

ZnO–SnO2 thin films were deposited by filtered vacuum arc deposition system and characterized using x-ray diffraction (XRD), energy dispersive spectroscopy, atomic force microscopy (AFM), spectrophotometer and ex situ variable angle spectroscopic ellipsometry. According to the XRD analysis the films were amorphous, independent of the deposition conditions. The root-mean-squares (RMS) of surface roughness and the average grain size obtained from the AFM images were 0.2–0.8 nm and 15–20 nm, respectively. Averaged optical transmission was 85%, and the refractive index and extinction coefficient of the films were in the range 2.05–2.28 and 0.001–0.044 at 500 nm wavelength, respectively. The range of the optical band gap of the films was 3.43–3.70 eV, depending on deposition conditions. The lowest resistivity was of the order of 10−2 Ω cm for films deposited on 400 °C heated substrates, while films deposited on substrates at room temperature were non-conducting, and films on 200 °C heated substrates were weakly conducting(∼101–2 Ω cm). The resistivity of films decreased with increasing pressure for 200 and 400 °C heated substrates relative to RT deposited films. The effect of deposition conditions on the optical constants was analysed statistically by single and two sided variance analysis, using the analysis code ‘Analysis Of Variance’ to determine the significance of the differences between sets. [ABSTRACT FROM AUTHOR]

Published

2006

66. Nanoparticle plasma ejected directly from solid copper by localized microwaves

Author

Barkay, Z [Wolfson Applied Materials Research Center, Tel Aviv University, Ramat-Aviv 69978 (Israel)]

Published

2009

67. Coherent radiation at visible wavelengths from sub-keV electron beams.

Author

Roitman D, Karnieli A, Tsesses S, Barkay Z, and Arie A

Abstract

The Smith-Purcell effect allows for coherent free-electron-driven compact light sources over the entire electromagnetic spectrum. Intriguing interaction regimes, with prospects for quantum optical applications, are expected when the driving free electron enters the sub-keV range, though this has until now remained an experimental challenge. Here, we demonstrate the Smith-Purcell light emission from UV to visible using engineerable, fabricated gratings with periodicities as low as 19 nm and with electron energies as low as 300 eV. Our findings constitute a major step toward broadband, highly tunable, on-chip light sources, observation of quantum recoil effects, and tunable EUV and x ray sources from swift electrons.

Published

2024

68. Sequential Solidification of Metal Powder by a Scanning Microwave Applicator.

Author

Shoshani Y, Weinstein T, Barkay Z, and Jerby E

Abstract

This study examines the fundamental feasibility of sequential metal-powder solidification by localized microwave-heating (LMH) provided by a scanning, all-solid-state microwave applicator. This continuous process is considered for the additive manufacturing (AM) and 3D printing (3DP) applications of metal parts. In previous studies, we employed LMH for the incremental solidification of small batches of metal powder in a stepwise vertical manner. Here, we study a continuous lateral LMH process, layer by layer, in a fashion similar to laser scanning in powder beds, as performed in common laser-based AM systems. LMH solidification at scanning rates of ~1 mm 3 /s is obtained in bronze powder using ~0.25-kW microwave power. The effect is studied here by LMH scanning in one lateral dimension (~20-mm long) in layers, each of ~1-4 mm thickness and ~2-4 mm width (mechanically confined). Imperfect solid bars of ~20×4×5 mm 3 are obtained with rough surfaces. Their joining in an L shape is also demonstrated. The experimental solidified products are tested, and their hardness and density properties are found to be comparable to laser-based AM products. The capabilities and limitations of the LMH scanning concept for metal-powder solidification are evaluated. The potential feasibility of a solid-state LMH-AM technology is discussed.

Published

2023

69. Measurement of the Anisotropic Dynamic Elastic Constants of Additive Manufactured and Wrought Ti6Al4V Alloys.

Author

Tevet O, Svetlizky D, Harel D, Barkay Z, Geva D, and Eliaz N

Abstract

Additively manufactured (AM) materials and hot rolled materials are typically orthotropic, and exhibit anisotropic elastic properties. This paper elucidates the anisotropic elastic properties (Young's modulus, shear modulus, and Poisson's ratio) of Ti6Al4V alloy in four different conditions: three AM (by selective laser melting, SLM, electron beam melting, EBM, and directed energy deposition, DED, processes) and one wrought alloy (for comparison). A specially designed polygon sample allowed measurement of 12 sound wave velocities (SWVs), employing the dynamic pulse-echo ultrasonic technique. In conjunction with the measured density values, these SWVs enabled deriving of the tensor of elastic constants ( C ij ) and the three-dimensional (3D) Young's moduli maps. Electron backscatter diffraction (EBSD) and micro-computed tomography (μCT) were employed to characterize the grain size and orientation as well as porosity and other defects which could explain the difference in the measured elastic constants of the four materials. All three types of AM materials showed only minor anisotropy. The wrought (hot rolled) alloy exhibited the highest density, virtually pore-free μCT images, and the highest ultrasonic anisotropy and polarity behavior. EBSD analysis revealed that a thin β-phase layer that formed along the elongated grain boundaries caused the ultrasonic polarity behavior. The finding that the elastic properties depend on the manufacturing process and on the angle relative to either the rolling direction or the AM build direction should be taken into account in the design of products. The data reported herein is valuable for materials selection and finite element analyses in mechanical design. The pulse-echo measurement procedure employed in this study may be further adapted and used for quality control of AM materials and parts.

Published

2022

70. Preserving Softness and Elastic Recovery in Silicone-Based Stretchable Electrodes Using Carbon Nanotubes.

Author

Bannych A, Katz S, Barkay Z, and Lachman N

Abstract

Soft electronics based on various rubbers have lately been needed in many advanced applications such as soft robotics, wearable electronics, and remote health monitoring. The ability of a self-sensing material to be monitored in use provides a significant advantage. However, conductive fillers usually used to increase conductivity also change mechanical properties. Most importantly, the initial sought-after properties of rubber, namely softness and long elastic deformation, are usually compromised. This work presents full mechanical and electro-mechanical characterization, together with self-sensing abilities of a vinyl methyl silicone rubber (VMQ) and multi-walled carbon nanotubes (MWCNTs) composite, featuring conductivity while maintaining low hardness. The research demonstrates that MWCNT/VMQ with just 4 wt.% of MWCNT are as conductive as commercial conductive VMQ based on Carbon Black, while exhibiting lower hardness and higher elastic recovery (~20% plastic deformation, similar to pure rubber). The research also demonstrates piezo-resistivity and Raman-sensitivity, allowing for self-sensing. Using morphological data, proposed mechanisms for the superior electrical and mechanical behavior, as well as the in-situ fingerprint for the composite conditions are presented. This research novelty is in the full MWCNT/VMQ mechanical and electro-mechanical characterization, thus demonstrating its ability to serve as a sensor over large local strains, multiple straining cycles, and environmental damage., Competing Interests: The authors declare no conflict of interest. The funders had no role in the design of the study; in the collection, analyses, or interpretation of data; in the writing of the manuscript, or in the decision to publish the results.

Published

2020

71. Soft corals form aragonite-precipitated columnar spiculite in mesophotic reefs.

Author

Shoham E, Prohaska T, Barkay Z, Zitek A, and Benayahu Y

Subjects

Animals, Anthozoa metabolism, Anthozoa ultrastructure, Calcium Carbonate metabolism, Magnesium analysis, Magnesium metabolism, Mass Spectrometry, Microscopy, Electron, Scanning, X-Ray Diffraction, Anthozoa chemistry, Calcium Carbonate analysis, Coral Reefs

Abstract

Surveys conducted in Eilat's upper mesophotic coral ecosystem (MCE) revealed protruding columnar calcareous structures with a Sinularia octocoral colony growing atop of each. The current study addressed the hypothesis that these colonies produce spiculites, and sought to determine (a) the spatial occurrence and dimensions of the spiculite-forming colonies and their species affiliation; (b) their microstructural features; and (c) the elemental composition of the columnar spiculites in comparison to the sclerites of the colonies. All the spiculite-forming colonies were exclusively found in the upper MCEs and produced by S. vrijmoethi. This type of spiculite, including its elemental analysis, is reported here for the first time for coral reefs in general and for the MCE in particular. Examination of the spiculites by scanning electron microscopy and energy-dispersive X-ray spectroscopy revealed spindle shaped-sclerites cemented by crystallites. The elemental composition of the sclerites differed from that of the cementing crystallites, in featuring ~8% Mg in the former and none in the latter. Inductively coupled plasma mass spectrometry revealed fragments of spiculite to be composed of 35% sclerites and 65% crystallites. X-ray powder diffraction analysis of individual sclerites indicated that they are composed exclusively of magnesium-calcite, and the spiculite fragments to also feature 9.3 ± 4% aragonite and 5-7% amorphous calcium carbonate. Consequently, it is proposed that the formation of the crystallites, which lithify the sclerites, is caused by a non-biogenic aragonite precipitation, and that the living colony might benefit from this protruding spiculite structure by means of enhanced exposure to water flow.

Published

2019

72. Controlled Formation of Radial Core-Shell Si/Metal Silicide Crystalline Heterostructures.

Author

Kosloff A, Granot E, Barkay Z, and Patolsky F

Abstract

The highly controlled formation of "radial" silicon/NiSi  core-shell nanowire heterostructures has been demonstrated for the first time. Here, we investigated the "radial" diffusion of nickel atoms into crystalline nanoscale silicon pillar 11 cores, followed by nickel silicide phase formation and the creation of a well-defined shell structure. The described approach is based on a two-step thermal process, which involves metal diffusion at low temperatures in the range of 200-400 °C, followed by a thermal curing step at a higher temperature of 400 °C. In-depth crystallographic analysis was performed by nanosectioning the resulting silicide-shelled silicon nanopillar heterostructures, giving us the ability to study in detail the newly formed silicide shells. Remarkably, it was observed that the resulting silicide shell thickness has a self-limiting behavior, and can be tightly controlled by the modulation of the initial diffusion-step temperature. In addition, electrical measurements of the core-shell structures revealed that the resulting shells can serve as an embedded conductive layer in future optoelectronic applications. This research provides a broad insight into the Ni silicide "radial" diffusion process at the nanoscale regime, and offers a simple approach to form thickness-controlled metal silicide shells in the range of 5-100 nm around semiconductor nanowire core structures, regardless the diameter of the nanowire cores. These high quality Si/NiSi core-shell nanowire structures will be applied in the near future as building blocks for the creation of utrathin highly conductive optically transparent top electrodes, over vertical nanopillars-based solar cell devices, which may subsequently lead to significant performance improvements of these devices in terms of charge collection and reduced recombination.

Published

2018

73. Plasma treatment switches the regime of wetting and floating of pepper seeds.

Author

Shapira Y, Multanen V, Whyman G, Bormashenko Y, Chaniel G, Barkay Z, and Bormashenko E

Subjects

Air, Hydrophobic and Hydrophilic Interactions, Surface Properties, Water, Plasma Gases, Seeds, Wettability

Abstract

Cold radiofrequency plasma treatment modified wetting and floating regimes of pepper seeds. The wetting regime of plasma-treated seeds was switched from the Wenzel-like partial wetting to the complete wetting. No hydrophobic recovery following the plasma treatment was registered. Environmental scanning electron microscopy of the fine structure of the (three-phase) triple line observed with virgin and plasma-treated seeds is reported. Plasma treatment promoted rapid sinking of pepper seeds placed on the water/air interface. Plasma treatment did not influence the surface topography of pepper seeds, while charged them electrically. Electrostatic repulsion of floating plasma-treated seeds was observed. The surface charge density was estimated from the data extracted from floating of charged seeds and independently with the electrostatic pendulum as σ≈1-2μC/m 2 ., (Copyright © 2017 Elsevier B.V. All rights reserved.)

Published

2017

74. Templated and self-limiting calcite formation directed by coccolith organic macromolecules.

Author

Gal A, Wirth R, Barkay Z, Eliaz N, Scheffel A, and Faivre D

Abstract

The formation of intricately shaped crystalline minerals by organisms is orchestrated by specialized biomacromolecules. The macromolecules associated with coccoliths, nanometer-sized calcite crystal arrays produced by marine microalgae, can form a distinct calcium-rich phase via macromolecular recognition. Here, we show that this calcium-rich phase can be mineralized into a thin film of single-crystalline calcite by the balanced addition of carbonate ions. Such a crystallization process provides a strategy to direct crystalline products via local interactions between soluble macromolecules and compatible templates.

Published

2017

75. On universality of scaling law describing roughness of triple line.

Author

Bormashenko E, Musin A, Whyman G, Barkay Z, and Zinigrad M

Abstract

The fine structure of the three-phase (triple) line was studied for different liquids, various topographies of micro-rough substrates and various wetting regimes. Wetting of porous and pillar-based micro-scaled polymer surfaces was investigated. The triple line was visualized with the environmental scanning electron microscope and scanning electron microscope for the "frozen" triple lines. The value of the roughness exponent ζ for water (ice)/rough polymer systems was located within 0.55-0.63. For epoxy glue/rough polymer systems somewhat lower values of the exponent, 0.42 < ζ < 0.54, were established. The obtained values of ζ were close for the Cassie and Wenzel wetting regimes, different liquids, and different substrates' topographies. Thus, the above values of the exponent are to a great extent universal. The switch of the exponent, when the roughness size approaches to the correlation length of the defects, is also universal.

Published

2015

76. Octocoral tissue provides protection from declining oceanic pH.

Author

Gabay Y, Fine M, Barkay Z, and Benayahu Y

Subjects

Animals, Hydrogen-Ion Concentration, Anthozoa growth & development, Carbon Dioxide chemistry, Oceans and Seas

Abstract

Increase in anthropogenic pCO2 alters seawater chemistry and could lead to reduced calcification or skeleton dissolution of calcifiers and thereby weaken coral-reef structure. Studies have suggested that the complex and diverse responses in stony coral growth and calcification, as a result of elevated pCO2, can be explained by the extent to which their soft tissues cover the underlying skeleton. This study compared the effects of decreased pH on the microstructural features of both in hospite (within the colony) and isolated sclerites (in the absence of tissue protection) of the zooxanthellate reef-dwelling octocoral Ovabunda macrospiculata. Colonies and isolated sclerites were maintained under normal (8.2) and reduced (7.6 and 7.3) pH conditions for up to 42 days. Both in hospite and isolated sclerites were then examined under SEM and ESEM microscopy in order to detect any microstructural changes. No differences were found in the microstructure of the in hospite sclerites between the control and the pH treatments. In stark contrast, the isolated sclerites revealed dissolution damage related to the acidity of the water. These findings suggest a protective role of the octocoral tissue against adverse pH conditions, thus maintaining them unharmed at high pCO2. In light of the competition for space with the less resilient reef calcifiers, octocorals may thus have a significant advantage under greater than normal acidic conditions.

Published

2014

77. In situ imaging of nano-droplet condensation and coalescence on thin water films.

Author

Barkay Z

Abstract

Two related aspects of nano-droplet condensation and droplets coalescence are studied for droplets on self-supported thin water films. The experiments are conducted in the environmental scanning electron microscope using wet scanning transmission electron microscopy. Favorable condensation sites are examined and in-situ position-controlled condensation experiments are conducted. The interaction among condensed multi-droplets as well as between a single droplet and the underneath nano-thick water film are dynamically examined with 10nm lateral resolution. The droplet round shape is reshaped to flat-like facets in-between droplets of 30-230 nm separation. Dynamic imaging of a few minutes duration shows a delayed coalescence effect, being explained by increased droplet-droplet electrostatic interaction relative to van der Waals interaction.

Published

2014

78. Unwrapping core-shell nanowires into nanoribbon-based superstructures.

Author

Pevzner A, Davidi G, Peretz-Soroka H, Havivi E, Barkay Z, Popovitz-Biro R, Khatchtourints A, and Patolsky F

Abstract

A prize for the ribbons: High-quality crystalline semiconducting nanoribbons can be prepared by "unwrapping" core-shell nanowire precursors. For example, Ge nanowires were coated with a Si shell and the top surface was carved by etching whereas the sides were protected by a thin layer of photoresist material. Finally the Ge core was removed selectively by chemical means to give fully opened and flat nanoribbon structures., (Copyright © 2013 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2013

79. Observations of Ball-Lightning-Like Plasmoids Ejected from Silicon by Localized Microwaves.

Author

Meir Y, Jerby E, Barkay Z, Ashkenazi D, Mitchell JB, Narayanan T, Eliaz N, LeGarrec JL, Sztucki M, and Meshcheryakov O

Abstract

This paper presents experimental characterization of plasmoids (fireballs) obtained by directing localized microwave power (<1 kW at 2.45 GHz) onto a silicon-based substrate in a microwave cavity. The plasmoid emerges up from the hotspot created in the solid substrate into the air within the microwave cavity. The experimental diagnostics employed for the fireball characterization in this study include measurements of microwave scattering, optical spectroscopy, small-angle X-ray scattering (SAXS), scanning electron microscopy (SEM) and energy dispersive X-ray spectroscopy (EDS). Various characteristics of these plasmoids as dusty plasma are drawn by a theoretical analysis of the experimental observations. Aggregations of dust particles within the plasmoid are detected at nanometer and micrometer scales by both in - situ SAXS and ex-situ SEM measurements. The resemblance of these plasmoids to the natural ball-lightning (BL) phenomenon is discussed with regard to silicon nano-particle clustering and formation of slowly-oxidized silicon micro-spheres within the BL. Potential applications and practical derivatives of this study (e.g., direct conversion of solids to powders, material identification by breakdown spectroscopy (MIBS), thermite ignition, and combustion) are discussed.

Published

2013

80. Development and characterization of composite YSZ-PEI electrophoretically deposited membrane for Li-ion battery.

Author

Hadar R, Golodnitsky D, Mazor H, Ripenbein T, Ardel G, Barkay Z, Gladkich A, and Peled E

Abstract

In this work, the electrophoretic-deposition (EPD) method was used to fabricate pristine and composite ceramic-polymer membranes for application in planar and 3D microbattery configurations. The major focus was on the effect of polyethyleneimine additive on the morphology, composition, and electrochemical properties of the membrane. The ionic conductivity, cycleability, and charge/discharge behavior of planar LiFePO(4)/Li cells comprising composite porous YSZ-based membrane with impregnated LiPF(6) EC:DEC electrolyte were found to be similar to the cells with commercial Celgard membrane. Conformal EPD coating of the electrode materials by a thin-film ceramic separator is advantageous for high-power operation and safety of batteries.

Published

2013

81. Confinement-guided shaping of semiconductor nanowires and nanoribbons: "writing with nanowires".

Author

Pevzner A, Engel Y, Elnathan R, Tsukernik A, Barkay Z, and Patolsky F

Subjects

Macromolecular Substances chemistry, Materials Testing, Molecular Conformation, Particle Size, Surface Properties, Crystallization methods, Nanostructures chemistry, Nanostructures ultrastructure, Nanotechnology methods, Semiconductors

Abstract

To fully exploit their full potential, new semiconductor nanowire building blocks with ab initio controlled shapes are desired. However, and despite the great synthetic advances achieved, the ability to control nanowire's geometry has been significantly limited. Here, we demonstrate a simple confinement-guided nanowire growth method that enables to predesign not only the chemical and physical attributes of the synthesized nanowires but also allows a perfect and unlimited control over their geometry. Our method allows the synthesis of semiconductor nanowires in a wide variety of two-dimensional shapes such as any kinked (different turning angles), sinusoidal, linear, and spiral shapes, so that practically any desired geometry can be defined. The shape-controlled nanowires can be grown on almost any substrate such as silicon wafer, quartz and glass slides, and even on plastic substrates (e.g., Kapton HN)., (© 2011 American Chemical Society)

Published

2012

82. Structural transition in peptide nanotubes.

Author

Amdursky N, Beker P, Koren I, Bank-Srour B, Mishina E, Semin S, Rasing T, Rosenberg Y, Barkay Z, Gazit E, and Rosenman G

Subjects

Microscopy, Electron, Scanning Transmission, Thermogravimetry, Wettability, X-Ray Diffraction, Nanotubes, Peptides chemistry

Abstract

Phase transitions in organic and inorganic materials are well-studied classical phenomena, where a change in the crystal space group symmetry induces a wide variation of physical properties, permitted by the crystalline symmetry in each phase. Here we observe a conformational induced transition in bioinspired peptide nanotubes (PNTs). We found that the PNTs change their original molecular assembly from a linear peptide conformation to a cyclic one, followed by a change of the nanocrystalline structure from a noncentrosymmetric hexagonal space group to a centrosymmetric orthorhombic space group. The observed transition is irreversible and induces a profound variation in the PNTs properties, from the microscopic to the macroscopic level. In this context, we follow the unique changes in the molecular, morphological, piezoelectric, second harmonic generation, and wettability properties of the PNTs.

Published

2011

83. Transparent metal nanowire thin films prepared in mesostructured templates.

Author

Azulai D, Belenkova T, Gilon H, Barkay Z, and Markovich G

Subjects

Electric Conductivity, Macromolecular Substances chemistry, Materials Testing, Molecular Conformation, Surface Properties, Crystallization methods, Gold chemistry, Membranes, Artificial, Nanotechnology methods, Nanotubes chemistry, Nanotubes ultrastructure, Silver chemistry

Abstract

The preparation of conductive and transparent gold/silver nanowire mesh films is reported. The nanowires formed after the reduction of the metal ions was triggered and a thin growth solution film was spread on a substrate. Metal reduction progressed within a template of a highly concentrated surfactant liquid crystalline mesostructure formed on the substrate during film drying to form ordered bundles of ultrathin nanowires. The films exhibited metallic conductivity over large areas, high transparency, and flexibility.

Published

2009

84. Enhanced osseointegration of grit-blasted, NaOH-treated and electrochemically hydroxyapatite-coated Ti-6Al-4V implants in rabbits.

Author

Lakstein D, Kopelovitch W, Barkay Z, Bahaa M, Hendel D, and Eliaz N

Subjects

Alloys, Animals, Equipment Failure Analysis, Femoral Fractures pathology, Prosthesis Design, Rabbits, Surface Properties, Durapatite chemistry, Electroplating methods, Femoral Fractures surgery, Osseointegration physiology, Prostheses and Implants, Sodium Hydroxide chemistry, Titanium chemistry

Abstract

Osseointegration, in terms of the bone apposition ratio (BAR) and the new bone area (NBA), was measured by backscattered electron imaging. The results were compared for four implant types: grit-blasted and NaOH-treated Ti-6Al-4V (Uncoated-NaOH), electrodeposited with hydroxyapatite without alkali treatment (ED-HAp), electrodeposited with hydroxyapatite after alkali treatment (NaOH-ED-HAp), and plasma sprayed with hydroxyapatite (PS-HAp). No heat treatment was done after soaking in NaOH. The implants were press fitted into the intramedullary canal of mature New Zealand white rabbits and analyzed, both at the diaphyseal and at the metaphyseal zones, either 1week or 12weeks after surgery. NaOH-ED-HAp already exhibited a higher BAR value than the ED-HAp at 1week, and was as good as the commercial PS-HAp at 12weeks. The NBA value for NaOH-ED-HAp at 12weeks was the highest. The higher content of octacalcium phosphate in NaOH-ED-HAp, as evident from the X-ray photoelectron spectroscopy analysis of the oxygen shake-up peaks, and the associated increase in the solubility of this coating in vivo are considered responsible for the enhanced osseointegration. Taking into account also the reduced occurrence of delamination and the inherent advantages of the electrodeposition process, electrodeposition of HAp following soaking in NaOH may become an attractive alternative for the traditional plasma-sprayed process for coating of orthopedic and dental implants.

Published

2009

85. Three-dimensional characterization of drug-encapsulating particles using STEM detector in FEG-SEM.

Author

Barkay Z, Rivkin I, and Margalit R

Subjects

Imaging, Three-Dimensional, Microscopy, Electron, Scanning Transmission instrumentation, Capsules, Drug Carriers, Microscopy, Electron, Scanning Transmission methods

Abstract

New drug-encapsulating particles were investigated using bright field (BF) scanning transmission electron microscopy (STEM) in a field emission gun (FEG) scanning electron microscope (SEM). Thickness characterization was done based on measuring the effective cross-section for interaction in our sample-detector configuration using calibration particles. A simplified analytical model, taking account of BF-STEM contrast and effective cross-section for interaction, was utilized for transforming projected two-dimensional BF-STEM images into three-dimensional thickness images. The three-dimensional characterization is demonstrated on a new family of biological materials composed of submicron to micron drug-free and drug-encapsulating particles. The importance of using BF-STEM in SEM, relative to other electron microscopy methods, is discussed as well as the lateral and depth resolution.

Published

2009

86. Secondary electron emission contrast of quantum wells in GaAs p-i-n junctions.

Author

Grunbaum E, Barkay Z, Shapira Y, Barnham KW, Bushnell DB, Ekins-Daukes NJ, Mazzer M, and Wilshaw P

Subjects

Quantum Theory, Surface Properties, Arsenicals chemistry, Gallium chemistry, Microscopy, Electron, Scanning methods, Nanostructures chemistry, Nanostructures ultrastructure

Abstract

The secondary electron (SE) signal over a cleaved surface of GaAs p-i-n solar cells containing stacks of quantum wells (QWs) is analyzed by high-resolution scanning electron microscopy. The InGaAs QWs appear darker than the GaAsP barriers, which is attributed to the differences in electron affinity. This method is shown to be a powerful tool for profiling the conduction band minimum across junctions and interfaces with nanometer resolution. The intrinsic region is shown to be pinned to the Fermi level. Additional SE contrast mechanisms are discussed in relation to the dopant regions themselves as well as the AlGaAs window at the p-region. A novel method of in situ observation of the SE profile changes resulting from reverse biasing these structures shows that the built-in potential may be deduced. The obtained value of 0.7 eV is lower than the conventional bulk value due to surface effects.

Published

2009

87. On the mechanism of floating and sliding of liquid marbles.

Author

Bormashenko E, Bormashenko Y, Musin A, and Barkay Z

Subjects

Air, Carbonates chemistry, Hydrophobic and Hydrophilic Interactions, Phenolphthalein chemistry, Polymers chemistry, Surface Properties, Water chemistry, Calcium Chloride chemistry, Sodium Hydroxide chemistry

Abstract

The mechanisms of floating and sliding of liquid marbles are studied. Liquid marbles containing CaCl(2) and marbles containing NaOH water solutions float on water containing Na(2)CO(3) and an alcoholic solution of phenolphthalein with no chemical reaction. Sliding of liquid marbles, consisting of NaOH water solutions, on polymer substrates coated with phenolphthalein is studied as well. No chemical reaction is observed. These observations supply direct experimental evidence for the suggestion that interfaces are separated by an air layer when marbles roll on solid substrates. It is concluded that a liquid marble rests on hydrophobic particles coating the liquid. In contrast, drops containing an NaOH water solution sliding on superhydrophobic surfaces coated with phenolphthalein leave a colored trace. The mechanism of low-friction sliding of drops deposited on superhydrophobic surfaces and liquid marbles turns out to be quite different: there is no direct contact between liquid and solid in the case of marbles' motion.

Published

2009

88. Shape, vibrations, and effective surface tension of water marbles.

Author

Bormashenko E, Pogreb R, Whyman G, Musin A, Bormashenko Y, and Barkay Z

Abstract

The surface of water "marbles" obtained with hydrophobic lycopodium and polyvinylidene fluoride particles was investigated first with environmental scanning electron microscopy. The shape of water marbles was studied both experimentally and theoretically. The mathematical model describing the deformation of marbles by gravity is proposed. The model allowed the calculation of the effective surface tension of marbles and gives 0.09 J/m2 for marbles coated with PVDF and 0.06 J/m2 for marbles coated with lycopodium. The effective surface tensions of marbles calculated independently by the horizontal vibration of marbles were in semiquantitative agreement with the above values (0.07 J/m2 for marbles coated with PVDF and 0.055 J/m2 for marbles coated with lycopodium).

Published

2009

89. Contact angle hysteresis on polymer substrates established with various experimental techniques, its interpretation, and quantitative characterization.

Author

Bormashenko E, Bormashenko Y, Whyman G, Pogreb R, Musin A, Jager R, and Barkay Z

Abstract

The effect of contact angle hysteresis (CAH) was studied on various polymer substrates with traditional and new experimental techniques. The new experimental technique presented in the article is based on the slow deformation of the droplet, thus CAH is studied under the constant volume of the drop in contrast to existing techniques when the volume of the drop is changed under the measurement. The energy of hysteresis was calculated in the framework of the improved Extrand approach. The advancing contact angle established with a new technique is in a good agreement with that measured with the needle-syringe method. The receding angles measured with three experimental techniques demonstrated a very significant discrepancy. The force pinning the triple line responsible for hysteresis was calculated.

Published

2008

90. Gravity orientation in social wasp comb cells (Vespinae) and the possible role of embedded minerals.

Author

Ishay JS, Barkay Z, Eliaz N, Plotkin M, Volynchik S, and Bergman DJ

Subjects

Animals, Gravitation, Minerals analysis, Social Behavior, Nesting Behavior, Orientation, Wasps physiology

Abstract

Social wasps and hornets maintain their nest in the dark. The building of the combs by all Vespinae is always in the direction of the gravitational force of Earth, and in each cell's ceiling, at least one 'keystone' is embedded and fastened by saliva. The sensory mechanisms that enable both building of sizeable symmetrical combs and nursing of the brood in the darkness merit investigation, and the aim of the present study was to identify and characterize the 'keystones' that exist in the ceiling and in the walls of the social wasp comb cells. Bio-ferrography was used to isolate magnetic particles on slides. These slides, as well as original cells, were analyzed in an environmental scanning electron microscope by a variety of analytical tools. It was found that both the roof and the walls of each comb cell bear minerals, like ferrites, as well as Ti and Zr. The latter two elements are less abundant in the soil around the nest. Ti and Zr are known to reflect infrared (IR) light. IR imaging showed a thermoregulatory center in the dorsal thorax of the adult Oriental hornet. It is not known yet whether these insects can sense IR light.

Published

2008

91. Environmental scanning electron microscopy study of the fine structure of the triple line and cassie-wenzel wetting transition for sessile drops deposited on rough polymer substrates.

Author

Bormashenko E, Bormashenko Y, Stein T, Whyman G, Pogreb R, and Barkay Z

Abstract

The wetting of rough honeycomb micrometrically scaled polymer substrates was studied. A very strong dependence of the apparent contact angle on the drop volume has been established experimentally. The environmental scanning electron microscopy study of the fine structure of the triple line is reported first. The triple line is not smooth and prefers grasping the polymer matrix over air holes. The precursor rim surrounding the drop has been observed. The revealed dependence of the apparent contact angle on the drop volume is explained by the transition between the pure Cassie and combined Wenzel-Cassie wetting regimes, which is induced by capillarity penetration of water into the holes of relief.

Published

2007

92. Silica-stabilized gold island films for transmission localized surface plasmon sensing.

Author

Ruach-Nir I, Bendikov TA, Doron-Mor I, Barkay Z, Vaskevich A, and Rubinstein I

Abstract

Ultrathin gold films prepared by evaporation of sub-percolation layers (typically up to 10 nm nominal thickness) onto transparent substrates form arrays of well-defined metal islands. Such films display a characteristic surface plasmon (SP) absorption band, conveniently measured by transmission spectroscopy. The SP band intensity and position are sensitive to the film morphology (island shape and inter-island separation) and the effective dielectric constant of the surrounding medium. The latter has been exploited for chemical and biological sensing in the transmission localized surface plasmon resonance (T-LSPR) mode. A major concern in the development of T-LSPR sensors based on Au island films is instability, manifested as change in the SP absorbance following immersion in organic solvents and aqueous solutions. The latter may present a problem in the use of Au island-based transducers for biological sensing, usually carried out in aqueous media. Here, we describe a facile method for stabilizing Au island films while maintaining a high sensitivity of the SP absorbance to analyte binding. Stabilization is achieved by coating the Au islands with an ultrathin silica layer, ca. 1.5 nm thick, deposited by a sol-gel procedure on an intermediate mercaptosilane monolayer. The silica coating is prepared using a modified literature procedure, where a change in the reaction conditions from room temperature to 90 degrees C shortened the deposition time from days to hours. The system was characterized by UV-vis spectroscopy, ellipsometry, XPS, HRSEM, AFM, and cyclic voltammetry. The ultrathin silica coating stabilizes the optical properties of the Au island films toward immersion in water, phosphate buffer saline (PBS), and various organic solvents, thus providing proper conditions where the optical response is sensitive only to changes in the effective dielectric constant of the immediate environment. The silica layer is thin enough to afford high T-LSPR sensitivity, while the hydroxyl groups on its surface enable chemical modification for binding of receptor molecules. The use of silica-encapsulated Au island films as a stable and effective platform for T-LSPR sensing is demonstrated.

Published

2007

93. Patterning in rapidly evaporated polymer solutions: formation of annular structures under evaporation of the poor solvent.

Author

Bormashenko E, Pogreb R, Musin A, Stanevsky O, Bormashenko Y, Whyman G, and Barkay Z

Abstract

Patterning in the intensively evaporated polymer solutions based on polystyrene and poor solvent (acetone) was investigated. SEM and AFM studies demonstrated that annular elements of the surface topography are formed in this case, in contrast to the honeycomb patterns obtained under the evaporation of the good solvent (chloroform). The authors suggest that the theory of viscous dewetting developed by de Gennes explains the phenomenon satisfactorily.

Published

2006

94. Self-assembly in evaporated polymer solutions: influence of the solution concentration.

Author

Bormashenko E, Pogreb R, Musin A, Stanevsky O, Bormashenko Y, Whyman G, Gendelman O, and Barkay Z

Abstract

Amorphous polymers were dissolved in chlorinated organic solvents and deposited on thin horizontal substrates. The solutions with various concentrations of polymers were deposited and evaporated under ambient conditions in a slow air current. Self-assembled oriented mesoscopically scaled patterns were observed. The patterns were studied with optical and atomic force microscopy. The concentration of the solution exerts a decisive influence on the mesoscopic cell characteristic dimension. Cell dimensions grow linearly with the polymer solution concentration for all kinds of tested polymers, chlorinated solvents and substrates. The dependence could be explained by a physical mechanism, based on the mass transport instability occurring under the intensive evaporation of the solvent. In situ FTIR study of the process was performed first. It was established with FTIR spectroscopy that film porosity is not due to water droplet condensation under evaporation.

Published

2006

95. The thermogenic center in social wasps.

Author

Ishay JS, Plotkin M, Ermakov NY, Volynchik S, Barkay Z, and Bergman DJ

Subjects

Animals, Infrared Rays, Male, Microscopy, Electron, Scanning, Photography, Thorax physiology, Wasps physiology, Body Temperature Regulation physiology, Thorax anatomy & histology, Wasps anatomy & histology

Abstract

In the social wasps Vespa orientalis and Paravespula germanica (Hymenoptera, Vespinae), a thermogenic center has been found in the dorsal part of the first thoracic segment. The temperature in this region of the prothorax is higher by 6-9 degrees C than that at the tip of the abdomen, and this in actively flying hornets outside the nest (workers, males or queens) as well as in hornets inside the nest that attend to the brood in the combs. On viewing the region from the outside, one discerns a canal or rather a fissure in the cuticle, which commences at the center of the dorsal surface of the prothorax and extends till the mesothorax. Thus the length of this canal or fissure is approximately 5-7 mm and it is seen to contain numerous thin hairs whose shape varies from that of the hairs alongside the structure. Beneath the cuticle in this region there are dorsoventral as well as longitudinal muscles in abundance, much the same as the musculature in the remaining thoracic segments (i.e. the meso- and metathorax), which activate the two pairs of wings. The canal-bearing segment is of course devoid of wings, and its dorsoventral muscles are attached to the cuticle, which in this region resembles a bowl harboring several layers of epithelium that boasts numerous butterfly-shaped tracheal branches. Additionally there are layers that display lymph-filled spaces and also perforated layers and depressions, and beneath all these is a lace-like layer that also coats the cuticle's hollows. Underneath the cuticle proper, there are numerous large mitochondria and tracheae, which occupy a considerable part of the cuticular epithelium surface. These abundant mitochondria are, most probably, the main element of heat production in the thermogenic center.

Published

2006

96. Antennal and cephalic organelles in the social wasp Paravespula germanica (Hymenoptera, Vespinae): form and possible function.

Author

Agmon I, Plotkin M, Ermakov NY, Barkay Z, and Ishay JS

Subjects

Animals, Extremities, Hair ultrastructure, Head, Microscopy, Atomic Force, Microscopy, Electron, Scanning, Photoreceptor Cells, Invertebrate ultrastructure, Sense Organs ultrastructure, Wasps ultrastructure

Abstract

This paper deals with hairs and organelles present on the head and antennae of the German wasp, Paravespula germanica, and their possible role in sensing the physical and chemical ambience, as well as in intercommunicating both while in flight outside or in the nest. Via scanning electron microscope photography, we detected on the frons plate of the wasp's head, hairs that were about 300 microm long and comprised the longest hairs on the body of the wasps. Additionally, the two antennae bore along their entire length photoreceptors, placoids, campaniforms, trichoids, and agmons. These organelles are located at high but variable density along the antennal segments. The paper provides the dimensions of each of the mentioned organelles, and discusses the possible functions of the organelles as well as of the hairs on the frons. Photographs taken via atomic force microscope reveal that the epicuticle of the antenna is of two typical shapes; one, bearing both longitudinal stripes as well as transverse bands that are about 1 mum in width, and a second granulated form. Conceivably, the wasp uses the various organelles mentioned to communicate with its mates that are some distance away, somewhat like the use of radar by humans., ((c) 2006 Wiley-Liss, Inc.)

Published

2006

97. A thermoregulatory center in hornets: IR photography.

Author

Plotkin M, Ermakov NY, Volynchik S, Barkay Z, Bergman DJ, and Ishay JS

Subjects

Animals, Body Temperature Regulation, Infrared Rays, Photography, Temperature, Body Temperature physiology, Wasps physiology

Abstract

In the Oriental hornet Vespa orientalis (Hymenoptera, Vespinae), there is on the dorsal side of the thorax, beneath the mesoscutum plate of the prothorax and around the median notal suture, a lump that, in the course of hornet activity, is warmer by 9 degrees C from the surrounding milieu and by up to 6 degrees C from other body parts of the hornet. This lump is about 1 mm in diameter, butterfly-shaped, and its upper, posterior border abuts the base of the forewings. During hornet activity and via Infra Red photography one can observe heat extensions stemming from the center of the lump and proceeding forward in the direction of the head, downward toward the legs and backwards toward the bases of the wings. The warmest region is the center of the lump, with its margins showing a lower temperature. As for the legs of the hornet, their upper part is warmer than the other parts. The temperature gradients along the hornet's body are dependent on the extent and nature of hornet activity. Thus, during flight or ventilation activity, the thorax is the warmest part of the body, while the wings, legs, and antennae, as well as the posterior part of the gaster are colder, yet all these body parts are still warmer to varying degrees than the surrounding milieu. Thus, at night, when sentry worker hornets stand guard around the nest entrance and remain practically motionless, the temperature differences between the various body parts are retained unchanged. We conjecture that the described butterfly-shaped lump is a thermoregulatory center (TC), which is neurogenically activated, since the changes occurring in it are rapid, a matter of one to several seconds and do not appear to be directly dependent on the hemolymph supply. The thermoregulatory center keeps a high constant temperature apparently related to hornet activity and the environmental conditions. The temperature cascade is most probably regulated via the tracheal system. Apparently another system activated by a heat pump mechanism keeps the gaster at a lower temperature than the environment., (Copyright (c) 2005 Wiley-Liss, Inc.)

Published

2005

98. Atomic force and scanning electron microscopy of atmospheric particles.

Author

Barkay Z, Teller A, Ganor E, Levin Z, and Shapira Y

Abstract

Atomic force microscopy (AFM) and scanning electron microscopy with energy dispersive spectroscopy (SEM-EDS) have been used for both morphological and elemental mass analysis study of atmospheric particles. As part of the geometrical particle analysis, and in addition to the traditional height profile measurement of individual particles, AFM was used to measure the volume relative to the projection area for each particle separately, providing a particle shape model. The element identification was done by the EDS analysis, and the element mass content was calculated based on laboratory calibration with particles of known composition. The SEM-EDS mass measurements from two samples collected at 150 and 500 m above the surface of the Mediterranean Sea were found to be similar to mass calculations derived from the AFM volume measurements. The AFM results show that the volume of most of the aerosols that were identified as soluble marine sulfate and nitrate aerosol particles can be better estimated using cylindrical shapes than spherical or conical geometry., (Copyright 2005 Wiley-Liss, Inc.)

Published

2005

99. Sensitivity of transmission surface plasmon resonance (T-SPR) spectroscopy: self-assembled multilayers on evaporated gold island films.

Author

Doron-Mor I, Cohen H, Barkay Z, Shanzer A, Vaskevich A, and Rubinstein I

Abstract

The distance dependence of the localized surface plasmon (SP) extinction of discontinuous gold films is a crucial issue in the application of transmission surface plasmon resonance (T-SPR) spectroscopy to chemical and biological sensing. This derives from the usual sensing configuration, whereby an analyte binds to a selective receptor layer on the gold film at a certain distance from the metal surface. In the present work the distance sensitivity of T-SPR spectroscopy of 1.0-5.0 nm (nominal thickness) gold island films evaporated on silanized glass substrates is studied by using coordination-based self-assembled multilayers, offering thickness tuning in the range from approximately 1 to approximately 15 nm. The morphology, composition and optical properties of the Au/multilayer systems were studied at each step of multilayer construction. High-resolution scanning electron microscopy (HRSEM) showed no apparent change in the underlying Au islands, while atomic force microscopy (AFM) indicated flattening of the surface topography during multilayer construction. A regular growth mode of the organic layers was substantiated by X-ray photoelectron spectroscopy (XPS). Transmission UV-visible spectra showed an increase of the extinction and a red shift of the maximum of the SP band upon addition of organic layers, establishing the distance dependence of the Au SP absorbance. The distance sensitivity of T-SPR spectroscopy can be varied by using characteristic substrate parameters, that is, Au nominal thickness and annealing. In particular, effective sensitivity up to a distance of at least 15 nm is demonstrated with 5 nm annealed Au films. It is shown that intensity measurements, particularly in the plasmon intensity change (PIC) presentation, provide an alternative to the usually measured plasmon band position, offering good accuracy and the possibility of measuring at a single wavelength. The present distance sensitivity results provide the basis for further development of T-SPR transducers based on receptor-coated Au island films.

Published

2005

100. Photolytic fabrication of phase gratings on silver halide crystals.

Author

Uman I, Nagli L, Barkay Z, Moser F, and Katzir A

Abstract

Diffraction phase gratings are formed on samples of crystalline silver halide by exposing them through a mask to 353-nm laser light followed by chemical processing. The exposure and photographic development processes generate metallic silver strips on the sample surface. The fixing process removes the silver strips, leaving grooves on the surface as deep as 1.1 microm. Gratings of 100-microm period are thus formed. The groove depth is determined by optical methods and is confirmed by atomic force microscopy. This method can be used to form diffractive optical elements on IR transmitting fibers and waveguides as well as on crystals.

Published

2002