Cone-shaped resonator-based highly efficient broadband polarization- independent metamaterial absorber for solar energy harvesting

Kumar, Raghvendra; Singh, Bipin; Pandey, Praveen C.

doi:10.21203/rs.3.rs-2280426/v1

Cited by 2 publications

(2 citation statements)

References 49 publications

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“…Many new models are ecofriendly and much cheaper and thinner than traditional silica (SiO2) solar cells. There are also inexpensive metals like iron, cobalt, and nickel that occur naturally which are instead used to create new metamaterial absorbers such as the saw-tooth coating, absorbing screens and the Cone-shaped resonator (Kumar et al, 2022). Recent advancements in computerized simulations and testing have yielded promising results, indicating that solar power generation companies should consider integrating the aforementioned metamaterial technologies.…”

Section: Future Prospects For Solar Harvestingmentioning

confidence: 99%

Application of Metamaterial in Renewable Energy: A Review

Ahmad,

Asad,

Pacpaco

et al. 2024

IJEMM

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Metamaterial advancements hold promise for compact renewable energy harvesting, capturing acoustic, electromagnetic, mechanical, and solar energy on a modest scale across global industries. Engineered structures surpass natural material limitations, offering capabilities unattainable in traditional counterparts. This investigation explores metamaterials' manipulation of acoustic, electromagnetic, mechanical, and solar energy. Mechanical metamaterials convert strain into electrical energy, applicable from interstellar travel to terrestrial infrastructure. Precision-configured acoustic metamaterials efficiently harness dispersed acoustic energy, improving renewable energy methodologies. Integration into photovoltaic cells showcases metamaterials' solar potential, with innovative designs enhancing solar energy conversion efficiency. Electromagnetic metamaterials efficiently absorb and convert frequencies into usable energy from communications and monitoring systems, in the agricultural and environmental sectors. Comparative analyses highlight noteworthy efficiency advancements, underscoring metamaterials' transformative influence on renewable energy. As they redefine the sector, implications extend to both small-scale devices and large-scale applications, positioning them as pivotal contributors. The paper critically evaluates metamaterial effectiveness in harnessing diverse energy sources, guiding future research. Metamaterial adaptability to different sizes and integration into technology reveals possibilities for compact energy sources. Ongoing research addresses scientific and economic challenges, paving the way for scaling metamaterial applications to commercial operations and emphasizing their importance in incorporating renewable energy into our technological milieu.

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Section: Future Prospects For Solar Harvestingmentioning

confidence: 99%

Application of Metamaterial in Renewable Energy: A Review

Ahmad,

Asad,

Pacpaco

et al. 2024

IJEMM

View full text Add to dashboard Cite

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“…To evaluate the performance of the solar cell, its absorption spectrum is compared with the AM1.5 solar radiation spectrum, as in Figure 2b [23]. The short circuit current density of the solar energy for AM1.5 is defined as [25]:…”

Section: Solar Cell Design Technologiesmentioning

confidence: 99%

Photovoltaic and Photothermal Solar Cell Design Principles: Efficiency/Bandwidth Enhancement and Material Selection

Raad¹,

Atlasbaf²

2023

Solar PV Panels - Recent Advances and Future Prospects

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There are two main approaches for developing solar cells, including photovoltaic and photothermal technologies. Photovoltaic solar cells benefit from an active region whose performance can be improved by embedding nanoparticles with different shapes and materials. Photothermal solar cells are broadband absorbers, enabling electromagnetic energy absorption in the solar radiation region. Since the solar spectrum is expanded from 120 to 1000 THz, the device bandwidth engineering and its efficiency enhancement through utilizing nanoparticles, multiresonance configurations, and multilayered structures are necessary. Moreover, using chemically inert materials with high thermal conductivities results in stable performance under different environmental conditions. Thus, in this chapter, various photovoltaic and photothermal solar cells will be discussed, emphasizing their design principles. The chapter mainly considers absorption bandwidth enlargement, absorption efficiency enhancement, and material selection considerations. In this regard, solar cells designed with plasmonic materials, transition metals, refractory metals, and carbon materials are presented. Notably, the potential of two-dimensional graphene material in the solar cell design is revealed, and a lightweight graphene-based solar cell with near-perfect coverage of the whole solar spectrum is introduced.

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Cone-shaped resonator-based highly efficient broadband polarization- independent metamaterial absorber for solar energy harvesting

Cited by 2 publications

References 49 publications

Application of Metamaterial in Renewable Energy: A Review

Application of Metamaterial in Renewable Energy: A Review

Photovoltaic and Photothermal Solar Cell Design Principles: Efficiency/Bandwidth Enhancement and Material Selection

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