Ting Xu scite author profile

Colour and spectral imaging systems typically use fi lters and glass prisms to disperse light of different wavelengths. With the miniaturization of integrated devices, current research on imaging sensors focuses on novel designs aiming at high effi ciency, low power consumption and slim dimension, which poses great challenges to the traditional colourant-based fi ltering and prismbased spectral splitting techniques. In this context, surface plasmon-based nanostructures are attractive due to their small dimensions and the ability to effi ciently manipulate light. In this article we use selective conversion between free-space waves and spatially confi ned modes in plasmonic nanoresonators formed by subwavelength metal -insulator -metal stack arrays to show that the transmission spectra through such arrays can be well controlled by using simple design rules, and high-effi ciency colour fi lters capable of transmitting arbitrary colours can be achieved. These artifi cial nanostructures provide an approach for high spatial resolution colour fi ltering and spectral imaging with extremely compact device architectures.

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Efficiency Enhancement of Organic Solar Cells Using Transparent Plasmonic Ag Nanowire Electrodes

Kang

et al. 2010

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Surface plasmon enhanced photo-current and power conversion efficiency of organic solar cells using periodic Ag nanowires as transparent electrodes are reported, as compared to the device with conventional ITO electrodes. External quantum efficiencies are enhanced about 2.5 fold around the peak solar spectrum wavelength of 560 nm, resulting in 35% overall increase in power conversion efficiency than the ITO control device under normal unpolarized light.

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All-angle negative refraction and active flat lensing of ultraviolet light

Agrawal

Abashin

et al. 2013

Nature

297

225

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Decades ago, Veselago predicted that a material with simultaneously negative electric and magnetic polarization responses would yield a 'left-handed' medium in which light propagates with opposite phase and energy velocities--a condition described by a negative refractive index. He proposed that a flat slab of left-handed material possessing an isotropic refractive index of -1 could act like an imaging lens in free space. Left-handed materials do not occur naturally, and it has only recently become possible to achieve a left-handed response using metamaterials, that is, electromagnetic structures engineered on subwavelength scales to elicit tailored polarization responses. So far, left-handed responses have typically been implemented using resonant metamaterials composed of periodic arrays of unit cells containing inductive-capacitive resonators and conductive wires. Negative refractive indices that are isotropic in two or three dimensions at microwave frequencies have been achieved in resonant metamaterials with centimetre-scale features. Scaling the left-handed response to higher frequencies, such as infrared or visible, has been done by shrinking critical dimensions to submicrometre scales by means of top-down nanofabrication. This miniaturization has, however, so far been achieved at the cost of reduced unit-cell symmetry, yielding a refractive index that is negative along only one axis. Moreover, lithographic scaling limits have so far precluded the fabrication of resonant metamaterials with left-handed responses at frequencies beyond the visible. Here we report the experimental implementation of a bulk metamaterial with a left-handed response to ultraviolet light. The structure, based on stacked plasmonic waveguides, yields an omnidirectional left-handed response for transverse magnetic polarization characterized by a negative refractive index. By engineering the structure to have a refractive index close to -1 over a broad angular range, we achieve Veselago flat lensing, in free space, of arbitrarily shaped, two-dimensional objects beyond the near field. We further demonstrate active, all-optical modulation of the image transferred by the flat lens.

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Ting Xu

Plasmonic nanoresonators for high-resolution colour filtering and spectral imaging

Efficiency Enhancement of Organic Solar Cells Using Transparent Plasmonic Ag Nanowire Electrodes

All-angle negative refraction and active flat lensing of ultraviolet light

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