Add to ORKGAn ultra-thin perfect absorber for deep ultraviolet light was realized using an Al/TiO2/AlN system. The TiO2 thickness was optimized using the Fresnel phasor diagram in complex space to achieve perfect light absorption. As a result of the calculation almost perfect absorption into the TiO2 film was found, despite the film being much thinner than the wavelength. An optimized Al/TiO2/AlN system was fabricated, and an average absorption greater than 97% was experimentally demonstrated at wavelengths of approximately 255–280 nm at normal light incidence. Our structure does not require nanopatterning processes, and this is advantageous for low-cost and large-area manufacturing
We demonstrate near-unity, broadband absorbing optoelectronic devices using sub-15 nm thick transiti...
In this paper, we demonstrate a facile, lithography free, and large scale compatible fabrication rou...
For ultrathin films of a given material, light absorption is proportional to the film thickness. How...
© OSA 2015. We show that perfect absorption can be achieved in ultra-thin gratings composed of weakl...
We show that perfect absorption can be achieved in a system comprising a single lossy dielectric lay...
Although different materials and designs have been tried in search of the ideal as well as ultrawide...
We experimentally demonstrate single beam directional perfect absorption (to within experimental acc...
© 2016 Optical Society of America. The perfect absorption of light in subwavelength thickness layers...
Highly reflective reflector (> 99.9%) operating at deep ultraviolet (DUV) wavelength region around 2...
In this paper, we propose a facile and large scale compatible design to obtain perfect ultrabroadban...
We experimentally demonstrate perfect absorption of incident light in an ultrathin, planar organic l...
Reducing device volume is one of the key requirements for advanced nanophotonic technologies; howeve...
<p> Plasmonic resonance of noble metal nanoparticles can drastically enhance the visible response o...
The spectral range of solar radiation observed on the earth is approximately 295 to 2500 nm. How to ...
Plasmonic is an emerging technology used to increase the performance of thin-film devices via light-...
We demonstrate near-unity, broadband absorbing optoelectronic devices using sub-15 nm thick transiti...
In this paper, we demonstrate a facile, lithography free, and large scale compatible fabrication rou...
For ultrathin films of a given material, light absorption is proportional to the film thickness. How...
© OSA 2015. We show that perfect absorption can be achieved in ultra-thin gratings composed of weakl...
We show that perfect absorption can be achieved in a system comprising a single lossy dielectric lay...
Although different materials and designs have been tried in search of the ideal as well as ultrawide...
We experimentally demonstrate single beam directional perfect absorption (to within experimental acc...
© 2016 Optical Society of America. The perfect absorption of light in subwavelength thickness layers...
Highly reflective reflector (> 99.9%) operating at deep ultraviolet (DUV) wavelength region around 2...
In this paper, we propose a facile and large scale compatible design to obtain perfect ultrabroadban...
We experimentally demonstrate perfect absorption of incident light in an ultrathin, planar organic l...
Reducing device volume is one of the key requirements for advanced nanophotonic technologies; howeve...
<p> Plasmonic resonance of noble metal nanoparticles can drastically enhance the visible response o...
The spectral range of solar radiation observed on the earth is approximately 295 to 2500 nm. How to ...
Plasmonic is an emerging technology used to increase the performance of thin-film devices via light-...
We demonstrate near-unity, broadband absorbing optoelectronic devices using sub-15 nm thick transiti...
In this paper, we demonstrate a facile, lithography free, and large scale compatible fabrication rou...
For ultrathin films of a given material, light absorption is proportional to the film thickness. How...