A model for efficient, semiconductor-free solar cells via supersensitized electron transfer cascades in photogalvanic devices

Halls, Jonathan E.; Wadhawan, Jay D.

doi:10.1039/c3cp00072a

Cited by 5 publications

(2 citation statements)

References 30 publications

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“…where is a matrix of known coefficients and and represent unknown and known equations, respectively, and is a vector of unknown and known equations. [26].…”

Section: Appendix A: An Undecadiagonal Matrix Algorithmmentioning

confidence: 99%

New approach for solving of Extended KdV Equation

Ramadan

Aly²

2022

Alfarama Journal of Basic & Applied Sciences

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“…where is a matrix of known coefficients and and represent unknown and known equations, respectively, and is a vector of unknown and known equations. [26].…”

Section: Appendix A: An Undecadiagonal Matrix Algorithmmentioning

confidence: 99%

New approach for solving of Extended KdV Equation

Ramadan

Aly²

2022

Alfarama Journal of Basic & Applied Sciences

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“…34%) when the supersensitizer concentration increases by an order of magnitude (from 5.0 to 50.0 mM). Under an AM 2.0 solar spectrum, this regenerative photogalvanic system is able to perform with a solar‐to‐electrical power conversion efficiency of 4.5%—an attractive realistic single cell value …”

Section: Solar Power Storage Efficiency Challenges and Future Resementioning

confidence: 99%

Photogalvanic cells: only solar cells having dual role of solar power generation and storage

Koli

2017

WIREs Energy & Environment

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Solar cell converts solar energy into electricity directly. Among such solar cells, the photogalvanic cells are unique as these are only solar cells that are capable of doing solar power generation and storage simultaneously. Therefore, such an inherent solar power storage capacity that too with good efficiency of these cells needs to be exploited for making solar cell technology a reliable source of power in the future. The fabrication and experimentation of photogalvanic cells is very simple to demonstrate its unique property. The power, short-circuit current, open-circuit potential, conversion efficiency, and power storage (in terms of half change time) for photogalvanic cells are reported of the order of 1159 μW, 4500 μA, 1.07 V, 14, and 260 min, respectively. However, to make photogalvanic cells realty in life for simultaneous solar power and storage, some challenges have to be tackled. Some of the challenges are photodecay of dye, corrosion of platinum (Pt), evaporation of liquid, breaking vulnerability of SCE/combination electrode, further need to increase the power and efficiency and storage, assembly operation of cells for augmentation of power, cell study in natural sunlight, and so on.

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Increasing photogalvanic solar power generation and storage capacity of brilliant cresyl blue by employing surfactant and natural sunlight

Koli

2024

Battery Energy

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Photogalvanic solar cells are solar energy harvesting devices having inherent power storage capacity. Electrical output as 590 μA current, 183.3 μW power, and 1.95% efficiency is reported for the fructose/brilliant cresyl blue dye (a reductant/photosensitizer couple) at low illumination intensity. For exploring the feasibility of these cells for application, the reported electrical output needs further enhancement with the demonstration of workability in natural sunlight. With this aim, the modified fructose reductant‐NaOH alkali‐brilliant cresyl blue dye photosensitizer photogalvanic system has been studied using a surfactant with a very small Pt electrode in natural sunlight. Abruptly enhanced current (2300 μA), power (661 μW), and efficiency (8.26%) have been observed in the modified study. The study has shown that photogalvanic cells can work at high illumination intensity adhering to similar basic principles, which are apt for cells working at artificial and low‐intensity illumination.

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A model for efficient, semiconductor-free solar cells via supersensitized electron transfer cascades in photogalvanic devices

Cited by 5 publications

References 30 publications

New approach for solving of Extended KdV Equation

New approach for solving of Extended KdV Equation

Photogalvanic cells: only solar cells having dual role of solar power generation and storage

Increasing photogalvanic solar power generation and storage capacity of brilliant cresyl blue by employing surfactant and natural sunlight

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