Your search keyword '"Infrared emitter"' showing total 3 results

1. Incandescent Light Bulbs Based on a Refractory Metasurface

Author

Hirofumi Toyoda, Kazunari Kimino, Akihiro Kawano, and Junichi Takahara

Subjects

incandescent light bulb, thermal radiation, refractory metal, microcavity, metamaterial, metasurface, surface plasmon, infrared emitter, nanoimprint, Applied optics. Photonics, TA1501-1820

Abstract

A thermal radiation light source, such as an incandescent light bulb, is considered a legacy light source with low luminous efficacy. However, it is an ideal energy source converting light with high efficiency from electric power to radiative power. In this work, we evaluate a thermal radiation light source and propose a new type of filament using a refractory metasurface to fabricate an efficient light bulb. We demonstrate visible-light spectral control using a refractory metasurface made of tantalum with an optical microcavity inserted into an incandescent light bulb. We use a nanoimprint method to fabricate the filament that is suitable for mass production. A 1.8 times enhancement of thermal radiation intensity is observed from the microcavity filament compared to the flat filament. Then, we demonstrate the thermal radiation control of the metasurface using a refractory plasmonic cavity made of hafnium nitride. A single narrow resonant peak is observed at the designed wavelength as well as the suppression of thermal radiation in wide mid-IR range under the condition of constant surface temperature.

Published

2019

2. Incandescent Light Bulbs Based on a Refractory Metasurface

Author

Akihiro Kawano, Junichi Takahara, Hirofumi Toyoda, and Kazunari Kimino

Subjects

lcsh:Applied optics. Photonics, Materials science, surface plasmon, Physics::Optics, 02 engineering and technology, nanoimprint, metamaterial, 01 natural sciences, law.invention, 010309 optics, law, 0103 physical sciences, Radiology, Nuclear Medicine and imaging, Instrumentation, Plasmon, Incandescent light bulb, incandescent light bulb, business.industry, infrared emitter, Metamaterial, lcsh:TA1501-1820, 021001 nanoscience & nanotechnology, Optical microcavity, Atomic and Molecular Physics, and Optics, Wavelength, metasurface, Thermal radiation, microcavity, Optoelectronics, thermal radiation, refractory metal, 0210 nano-technology, Luminous efficacy, business, Energy source

Abstract

A thermal radiation light source, such as an incandescent light bulb, is considered a legacy light source with low luminous efficacy. However, it is an ideal energy source converting light with high efficiency from electric power to radiative power. In this work, we evaluate a thermal radiation light source and propose a new type of filament using a refractory metasurface to fabricate an efficient light bulb. We demonstrate visible-light spectral control using a refractory metasurface made of tantalum with an optical microcavity inserted into an incandescent light bulb. We use a nanoimprint method to fabricate the filament that is suitable for mass production. A 1.8 times enhancement of thermal radiation intensity is observed from the microcavity filament compared to the flat filament. Then, we demonstrate the thermal radiation control of the metasurface using a refractory plasmonic cavity made of hafnium nitride. A single narrow resonant peak is observed at the designed wavelength as well as the suppression of thermal radiation in wide mid-IR range under the condition of constant surface temperature.

Published

2019

3. Incandescent Light Bulbs Based on a Refractory Metasurface †.

Author

Toyoda, Hirofumi, Kimino, Kazunari, Kawano, Akihiro, and Takahara, Junichi

Subjects

LIGHT bulbs, HEAT radiation & absorption, RADIATION sources, LIGHT sources, MASS production, ELECTRIC power

Abstract

A thermal radiation light source, such as an incandescent light bulb, is considered a legacy light source with low luminous efficacy. However, it is an ideal energy source converting light with high efficiency from electric power to radiative power. In this work, we evaluate a thermal radiation light source and propose a new type of filament using a refractory metasurface to fabricate an efficient light bulb. We demonstrate visible-light spectral control using a refractory metasurface made of tantalum with an optical microcavity inserted into an incandescent light bulb. We use a nanoimprint method to fabricate the filament that is suitable for mass production. A 1.8 times enhancement of thermal radiation intensity is observed from the microcavity filament compared to the flat filament. Then, we demonstrate the thermal radiation control of the metasurface using a refractory plasmonic cavity made of hafnium nitride. A single narrow resonant peak is observed at the designed wavelength as well as the suppression of thermal radiation in wide mid-IR range under the condition of constant surface temperature. [ABSTRACT FROM AUTHOR]

Published

2019