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Numerous applications, including communications, sensing, lighting, photography, and energy harvesting, use Nanoparticle-based optical filters . The majority of Nanoparticle-based optical filters made today are either added to transparent solids like glasses and plastics or deposition is used to deposit components onto solid substrates .
The concept of tuning Nanoparticle-based optical filters with nanoparticles is useful . Such filters might be pushed into and out of a system, providing the capacity to meet momentary requirements of an application. But right now, study of liquid filters is still largely unexplored. Only a few ‘pure’ fluid filters with acceptable optical characteristics have been researched up to this point.
The Global Nanoparticle-based optical filter market accounted for $XX Billion in 2022 and is anticipated to reach $XX Billion by 2030, registering a CAGR of XX% from 2023 to 2030.
Recent modeling and design work suggests that liquid-based Nanoparticle-based optical filters can replace traditional optical filters.
The ability of Nanoparticle-based optical filters to be pumped into and out of a system to suit temporary demands in an application is the primary driving force behind their development. the design of nanofluids for use as long-pass, short-pass, and bandpass optical filters using a straightforward Monte Carlo optimization approach to illustrate the adaptability of this new class of filters.
Researchers are able to produce filters with a mean-squared transmittance deviation from typical filters of 15% with reasonably simple mixes. By estimating the current off-the-shelf price of the materials, researchers can also talk about the commercial viability of nanofluid-based optical filters.
A wide range of applications, including optical communications, electronics, lighting, optical sensors, and photography, need the use of optical filters. Recent research suggests that solutions of specific nanoparticles can be used to make Nanoparticle-based optical filters.
The theoretical optimization procedure for creating Nanoparticle-based optical filters for hybrid solar photovoltaic/thermal (PV/T) applications is specifically covered in this paper.
Nanofluids can be used in this specific application as both flowing heat transfer media and volumetric solar absorbers. Five different photovoltaic (PV) cell alternatives—InGaP, CdTe, InGaAs, Si, and Ge—compare favorably to the nanofluid filters used in what follows when compared to traditional optical filters.
This shows that spectrally Nanoparticle-based optical filters made of nanofluids are effective, small, and possibly inexpensive.
