Add to ORKGMetals in the plasmonic metamaterial absorbers for photovoltaics constitute undesired resistive heating. However, tailoring the geometric skin depth of metals can minimize resistive losses while maximizing the optical absorbance in the active semiconductors of the photovoltaic device. Considering experimental permittivity data for InxGa1-xN, absorbance in the semiconductor layers of the photovoltaic device can reach above 90%. The results here also provides guidance to compare the performance of different semiconductor materials. This skin depth engineering approach can also be applied to other optoelectronic devices, where optimizing the device performance demands minimizing resistive losses and power consumption, such as photodetectors, l...
In a race to reduce the cost per Watt of solar generated power, there is generally a tradeoff betwee...
If the active layer of efficient solar cells could be made 100 times thinner than in today\u27s thin...
This chapter reviews the recent promising advances in the use of plasmonic nanostructures forming me...
Metals in the plasmonic metamaterial absorbers for photovoltaics constitute undesired resistive heat...
Using metamaterial absorbers, we have shown that metallic layers in the absorbers do not necessarily...
Plasmonic is an emerging technology used to increase the performance of thin-film devices via light-...
Maximum absorption of light using plasmonic perfect absorbers (PPAs) is highly desired in the field ...
We systematically explore the performance of ultrathin amorphous silicon solar cells integrated on p...
ABSTRACT: We demonstrate a broadband, polarization independent, omnidirectional absorber based on a ...
For ultrathin films of a given material, light absorption is proportional to the film thickness. How...
<div>Maximum absorption of light using plasmonic perfect absorbers (PPAs) is highly desired in the f...
In a race to reduce the cost per Watt of solar generated power, there is generally a tradeoff betwee...
For ultrathin (similar to 10 nm) nanocomposite films of plasmonic materials and semiconductors, the ...
The challenge when applying photonics to photovoltaics is the need to provide broadband, multiple-an...
A dual band metamaterial absorber is designed for photovoltaic applications. The novelty of the desi...
In a race to reduce the cost per Watt of solar generated power, there is generally a tradeoff betwee...
If the active layer of efficient solar cells could be made 100 times thinner than in today\u27s thin...
This chapter reviews the recent promising advances in the use of plasmonic nanostructures forming me...
Metals in the plasmonic metamaterial absorbers for photovoltaics constitute undesired resistive heat...
Using metamaterial absorbers, we have shown that metallic layers in the absorbers do not necessarily...
Plasmonic is an emerging technology used to increase the performance of thin-film devices via light-...
Maximum absorption of light using plasmonic perfect absorbers (PPAs) is highly desired in the field ...
We systematically explore the performance of ultrathin amorphous silicon solar cells integrated on p...
ABSTRACT: We demonstrate a broadband, polarization independent, omnidirectional absorber based on a ...
For ultrathin films of a given material, light absorption is proportional to the film thickness. How...
<div>Maximum absorption of light using plasmonic perfect absorbers (PPAs) is highly desired in the f...
In a race to reduce the cost per Watt of solar generated power, there is generally a tradeoff betwee...
For ultrathin (similar to 10 nm) nanocomposite films of plasmonic materials and semiconductors, the ...
The challenge when applying photonics to photovoltaics is the need to provide broadband, multiple-an...
A dual band metamaterial absorber is designed for photovoltaic applications. The novelty of the desi...
In a race to reduce the cost per Watt of solar generated power, there is generally a tradeoff betwee...
If the active layer of efficient solar cells could be made 100 times thinner than in today\u27s thin...
This chapter reviews the recent promising advances in the use of plasmonic nanostructures forming me...