Ofer Shapira scite author profile

Virtually all electronic and optoelectronic devices necessitate a challenging assembly of conducting, semiconducting and insulating materials into specific geometries with low-scattering interfaces and microscopic feature dimensions. A variety of wafer-based processing approaches have been developed to address these requirements, which although successful are at the same time inherently restricted by the wafer size, its planar geometry and the complexity associated with sequential high-precision processing steps. In contrast, optical-fibre drawing from a macroscopic preformed rod is simpler and yields extended lengths of uniform fibres. Recently, a new family of fibres composed of conductors, semiconductors and insulators has emerged. These fibres share the basic device attributes of their traditional electronic and optoelectronic counterparts, yet are fabricated using conventional preform-based fibre-processing methods, yielding kilometres of functional fibre devices. Two complementary approaches towards realizing sophisticated functions are explored: on the single-fibre level, the integration of a multiplicity of functional components into one fibre, and on the multiple-fibre level, the assembly of large-scale two- and three-dimensional geometric constructs made of many fibres. When applied together these two approaches pave the way to multifunctional fabric systems.

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Observation and Differentiation of Unique High-QOptical Resonances Near Zero Wave Vector in Macroscopic Photonic Crystal Slabs

Lee

et al. 2012

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We demonstrate and distinguish experimentally the existence of a special type of Fano resonances at k≈0 in a macroscopic two-dimensional photonic crystal slab. We fabricate a square lattice array of holes in a silicon nitride layer and perform an angular resolved spectral analysis of the various Fano resonances. We elucidate their radiation behavior using temporal coupled-mode theory and symmetry considerations. The unique simplicity of this system whereby an ultralong lifetime delocalized electromagnetic field can exist above the surface and consequently easily interact with added matter, provides exciting new opportunities for the study of light and matter interaction.

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Transparent displays enabled by resonant nanoparticle scattering

et al. 2014

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The ability to display graphics and texts on a transparent screen can enable many useful applications. Here we create a transparent display by projecting monochromatic images onto a transparent medium embedded with nanoparticles that selectively scatter light at the projected wavelength. We describe the optimal design of such nanoparticles, and experimentally demonstrate this concept with a blue-color transparent display made of silver nanoparticles in a polymer matrix. This approach has attractive features including simplicity, wide viewing angle, scalability to large sizes and low cost.

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Large-scale optical-field measurements with geometric fibre constructs

et al. 2006

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Optical fields are measured using sequential arrangements of optical components such as lenses, filters, and beam splitters in conjunction with planar arrays of point detectors placed on a common axis. All such systems are constrained in terms of size, weight, durability and field of view. Here a new, geometric approach to optical-field measurements is presented that lifts some of the aforementioned limitations and, moreover, enables access to optical information on unprecedented length and volume scales. Tough polymeric photodetecting fibres drawn from a preform are woven into light-weight, low-optical-density, two- and three-dimensional constructs that measure the amplitude and phase of an electromagnetic field on very large areas. First, a three-dimensional spherical construct is used to measure the direction of illumination over 4pi steradians. Second, an intensity distribution is measured by a planar array using a tomographic algorithm. Finally, both the amplitude and phase of an optical wave front are acquired with a dual-plane construct. Hence, the problem of optical-field measurement is transformed from one involving the choice and placement of lenses and detector arrays to that of designing geometrical constructions of polymeric, light-sensitive fibres.

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Multimaterial Photodetecting Fibers: a Geometric and Structural Study

et al. 2007

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The recent development of codrawn metal-insulator-semiconductor photodetecting fiber devices with mesoscopic-scale cross-sectional features has heralded a novel path to optical radiation detection. [1][2][3][4][5][6][7][8] For the first time, optical detection function may be delivered at length scales and in a mechanically flexible form hitherto associated with optical fibers. At the heart of the fabrication process is the simultaneous reduction of the cross-section and extension of the axial dimensions of a macroscopic prefrom. Thermal drawing results in extended length scales of functional fiber while maintaining the material composition and transverse geometry throughout. Although beneficial for many applications, [1,2,5,6] the extended length scales of fiber-devices tend to degrade their performance by raising the noise floor. Our study aims to minimize the noise per unit length by identifying optimal fiber structures and geometries. A comparative study of the responsivity, noise and sensitivity [9,10] of photodetecting fibers as a function of structural and geometric scaling parameters is performed. A novel thin-film photodetecting fiber device architecture is introduced. Precise control over the submicron scale dimensions affords more than an order of magnitude increase in the fiber-device sensitivity. Potential applications of fiber devices include remote sensing, functional fabrics, and largearea, two-dimensional (2D) and three-dimensional (3D) arrays (or "fiber webs") capable of optical imaging. [1,5,6]

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Ofer Shapira

Towards multimaterial multifunctional fibres that see, hear, sense and communicate

Observation and Differentiation of Unique High-QOptical Resonances Near Zero Wave Vector in Macroscopic Photonic Crystal Slabs

Transparent displays enabled by resonant nanoparticle scattering

Large-scale optical-field measurements with geometric fibre constructs

Multimaterial Photodetecting Fibers: a Geometric and Structural Study

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