Color Sensing by Optical Antennas: Approaching the Quantum Efficiency Limit

Tamang, Asman; Parsons, Rion; Palanchoke, Ujwol; Stiebig, Helmut; Wagner, Veit; Salleo, Alberto; Knipp, Dietmar

doi:10.1021/acsphotonics.9b00490

Cited by 12 publications

(23 citation statements)

References 41 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…As illustrated in Figure c, Si disks are used along with an antireflection coating to achieve the so-called Kerker’s conditions that sharpen up reflectance transitions. Doing so brings one closer to the boxcar-shaped reflectance profiles leading to a color gamut exceeding the sRGB color space, that is, occupying ∼120% of the sRGB color space. , Another area where structural colors can be applied is in color filtering. − Due to their nanoscale footprint and the ability to be tuned over the visible spectra, structural colors can further miniaturize the imaging sensors by reducing the size of color filters. − Figure d depicts a configuration for color filtering. By adjusting the cavity thickness, the spectra can be continuously tuned over visible spectra .…”

Section: Structural Color Generation Methods and Relevant Applicationsmentioning

confidence: 99%

Nanophotonic Structural Colors

et al. 2020

View full text Add to dashboard Cite

Structural colors traditionally refer to colors arising from the interaction of light with structures with periodicities on the order of the wavelength. Recently, the definition has been broadened to include colors arising from individual resonators that can be subwavelength in dimension, e.g., plasmonic and dielectric nanoantennas. For instance, diverse metallic and dielectric nanostructure designs have been utilized to generate structural colors based on various physical phenomena, such as localized surface plasmon resonances (LSPRs), Mie resonances, thin-film Fabry-Pérot interference, and Rayleigh-Wood diffraction anomalies from 2D periodic lattices and photonic crystals. Here, we provide our perspective of the key application areas where structural colors really shine, and other areas where more work is needed. We review major classes of materials and structures employed to generate structural coloration and highlight the main physical resonances involved.

show abstract

Section: Structural Color Generation Methods and Relevant Applicationsmentioning

confidence: 99%

Nanophotonic Structural Colors

et al. 2020

View full text Add to dashboard Cite

show abstract

“…The solar cell consists of an array of nanowires or nanodisks. Each nanowire or nanodisk acts like a circular resonator. − The optical resonator supports whispering gallery or leaky modes . The light is repeatedly reflected by the circular boundary of the optical resonator.…”

Section: Experimental Sectionmentioning

confidence: 99%

“…The effective wavelength is given by λ eff = λ 0 / n eff , where n eff is the effective refractive index, which varies between the refractive index of the cladding (air) and the refractive index of the core and λ 0 is the vacuum wavelength . Optical mode theory can be used to calculate the effective refractive index. − , …”

Section: Experimental Sectionmentioning

confidence: 99%

“…Both approaches have been described in the literature. ,,,, We have investigated thin-film materials that can be directly deposited on a glass substrate at low temperatures. We investigated the use of crystalline, microcrystalline, and amorphous silicon materials. ,, All three materials have been intensively researched as photovoltaic materials. However, crystalline silicon requires the use of high deposition temperatures that are not compatible with the use of solar glass .…”

Section: Experimental Sectionmentioning

confidence: 99%

See 1 more Smart Citation

Combining Photosynthesis and Photovoltaics: A Hybrid Energy-Harvesting System Using Optical Antennas

Tamang

Parsons

Lertchaiwarakul

et al. 2020

ACS Appl. Mater. Interfaces

Self Cite

View full text Add to dashboard Cite

A hybrid energy-harvesting system is proposed that combines photosynthesis and photovoltaics. First, the light passes through a spectrally selective solar cell, which absorbs almost all green light but absorbs almost no blue and red light. The blue and red light are absorbed by a photosynthesis executing plant. The solar cell is tailored in such a way that the photosynthetic process is almost unaffected by the generation of electrical energy. The spectrally selective solar cell consists of an array of inorganic optical antennas. By combining a spectrally selective solar cell and a photosynthetic executing plant, a hybrid energy system is formed, which absorbs almost 100% of the visible light, while the energy conversion efficiency of the solar cell reaches up to 50% of their nonspectrally selective counterparts. Guidelines are provided on how to realize both the highly efficient spectrally selective solar cells and hybrid energy-harvesting systems. The proposed solution allows for the realization of new greenhouses or gardens covered with spectrally selective transparent solar cells that produce chemical energy in the form of fruits and vegetables and electrical energy.

show abstract

“…Theoretically, this can increase the photon collection on average by 3×, with additional improvements possible for front-illuminated CMOS configurations (where often only 50% of the illuminated surface is photoactive) ( Zhang et al., 2010 ), due to built-in lensing/funneling ( Sounas and Alu, 2016 ; Johlin et al., 2018 ). Color splitting for imaging applications has been investigated previously through fairly complex processes ( Chen et al., 2016 ), often involving high-index material processing steps ( Sounas and Alu, 2016 ; Miyata et al., 2019 ; Chen et al., 2017 ; Nishiwaki et al., 2013 ; Tamang et al., 2019 ; Zhao et al, 2020 ), new elements in the far-field of the sensor ( Miyata et al., 2019 ; Chen et al., 2017 ; Nishiwaki et al., 2013 ; Xiao et al., 2016 ; Camayd-Muñoz et al., 2020 ), and computationally expensive image reconstructions ( Wang and Menon, 2015 ; Sahoo et al., 2017 ). Many designs additionally only work with a specific polarization of light, limiting their efficiency for normal imaging applications ( Xu et al., 2010 ; Nguyen-Huu et al., 2011 ; Kanamori et al., 2006 ).…”

Section: Introductionmentioning

confidence: 99%

Nanophotonic color splitters for high-efficiency imaging

Johlin

2021

iScience

View full text Add to dashboard Cite

Summary Standard color imaging utilizes absorptive filter arrays to achieve spectral sensitivity. However, this leads to ∼2/3 of incident light being lost to filter absorption. Instead, splitting and redirecting light into spatially separated pixels avoids these absorptive losses. Herein we investigate the inverse design and performance of a new type of splitter which can be printed from a single material directly on top of a sensor surface and are compatible with 800 nm sensor pixels, thereby providing drop-in replacements for color filters. Two-dimensional structures with as few as four layers significantly improve fully color-corrected imaging performance over standard filters, with lower complexity. Being fully dielectric, these splitters additionally allow color-correction to be foregone, increasing the photon transmission efficiency to over 80%, even for sensors with fill-factors of 0.5. Performance further increases with fully 3D structures, improving light sensitivity in color-corrected imaging by a factor of 4 when compared to filters alone.

show abstract

Color Sensing by Optical Antennas: Approaching the Quantum Efficiency Limit

Cited by 12 publications

References 41 publications

Nanophotonic Structural Colors

Nanophotonic Structural Colors

Combining Photosynthesis and Photovoltaics: A Hybrid Energy-Harvesting System Using Optical Antennas

Nanophotonic color splitters for high-efficiency imaging

Contact Info

Product

Resources

About