Hybrid Solar PVT Systems for Thermal Energy Storage: Role of Nanomaterials, Challenges, and Opportunities

Rashmi, W.; Mahesh, Vinyas; Anirban, S.; Sharnil, P.; Khalid, Mohammad

doi:10.1007/978-981-16-1256-5_9

Cited by 2 publications

(2 citation statements)

References 97 publications

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“…A fill factor of at least 70% is required for a PV module of decent quality 14 . Lower fill factors imply higher values for

R_{s}

or lower values for

R_{italicsh}

, larger recombination currents in the space charge zone, and higher junction

I_{o}

reverse saturation currents, all of which predict higher losses 15 . In order to improve the performance of PV cell, the environmental analysis needs to be done.…”

Section: Introductionmentioning

confidence: 99%

“…14 Lower fill factors imply higher values for R s or lower values for R sh , larger recombination currents in the space charge zone, and higher junction I o reverse saturation currents, all of which predict higher losses. 15 In order to improve the performance of PV cell, the environmental analysis needs to be done. The factors such as irradiation, PV production of each location, the cost of equipment may vary from one location to another.…”

mentioning

confidence: 99%

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Gallium indium nitrate doped PbS and MoS₂ with ligands based photovoltaic cell structure for enhanced efficiency incorporating transformer based module with hydro Ferron chloride thermal sub cell cooling system

Kumar

Alam²

2023

Env Prog and Sustain Energy

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A solar photovoltaic cell that is efficient and produces more power while taking up less area by absorbing high‐light energy. To improve the efficiency of the photovoltaic cell (PV), recombination technique is used in the absorption layers of the solar cell. The existing recombination techniques developed by the absorbers have weak interconnectivity, which may leads to defects, and efficiency is reduced due to the high resistance in diffusion length. So, “GNI‐doped PbS and MoS2 with ligands‐based PV structure” is proposed to improve the interconnection between the layers of the Solar cell. Here, gallium nitride (GaN) and indium nitride (InN) act as anode and cathode in first and third layer, to get the better interconnection by interchanging oxide ions where the Gallium Indium nitrate used as semiconductor. To improve the durability, second layer is doped with Bi3+ with Fe3+, which has a rhombohedral perovskite structure. Molybdenum di‐Sulfide (MoS2) is used in the last layer to improve light absorption. To maintain surface passivation, transformer‐based PV module with an HFC Thermal sub cell is employed in which Hydro Ferron chloride combined with Nano graphene platelets is to avoid Potential Induced Degradation and transformers to eliminate the stray current. While implementing, with very low cost the power conversion efficiency of proposed design increased upto 17%.

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“…A fill factor of at least 70% is required for a PV module of decent quality 14 . Lower fill factors imply higher values for

R_{s}

or lower values for

R_{italicsh}

, larger recombination currents in the space charge zone, and higher junction

I_{o}

reverse saturation currents, all of which predict higher losses 15 . In order to improve the performance of PV cell, the environmental analysis needs to be done.…”

Section: Introductionmentioning

confidence: 99%

mentioning

confidence: 99%

Gallium indium nitrate doped PbS and MoS₂ with ligands based photovoltaic cell structure for enhanced efficiency incorporating transformer based module with hydro Ferron chloride thermal sub cell cooling system

Kumar

Alam²

2023

Env Prog and Sustain Energy

View full text Add to dashboard Cite

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Photovoltaic thermal system with phase changing materials and MWCNT nanofluids for high thermal efficiency and hydrogen production

Liu

Ning

Pan

et al. 2024

Fuel

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Hybrid Solar PVT Systems for Thermal Energy Storage: Role of Nanomaterials, Challenges, and Opportunities

Cited by 2 publications

References 97 publications

Gallium indium nitrate doped PbS and MoS₂ with ligands based photovoltaic cell structure for enhanced efficiency incorporating transformer based module with hydro Ferron chloride thermal sub cell cooling system

Gallium indium nitrate doped PbS and MoS₂ with ligands based photovoltaic cell structure for enhanced efficiency incorporating transformer based module with hydro Ferron chloride thermal sub cell cooling system

Photovoltaic thermal system with phase changing materials and MWCNT nanofluids for high thermal efficiency and hydrogen production

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Hybrid Solar PVT Systems for Thermal Energy Storage: Role of Nanomaterials, Challenges, and Opportunities

Cited by 2 publications

References 97 publications

Gallium indium nitrate doped PbS and MoS2 with ligands based photovoltaic cell structure for enhanced efficiency incorporating transformer based module with hydro Ferron chloride thermal sub cell cooling system

Gallium indium nitrate doped PbS and MoS2 with ligands based photovoltaic cell structure for enhanced efficiency incorporating transformer based module with hydro Ferron chloride thermal sub cell cooling system

Photovoltaic thermal system with phase changing materials and MWCNT nanofluids for high thermal efficiency and hydrogen production

Contact Info

Product

Resources

About

Gallium indium nitrate doped PbS and MoS₂ with ligands based photovoltaic cell structure for enhanced efficiency incorporating transformer based module with hydro Ferron chloride thermal sub cell cooling system

Gallium indium nitrate doped PbS and MoS₂ with ligands based photovoltaic cell structure for enhanced efficiency incorporating transformer based module with hydro Ferron chloride thermal sub cell cooling system