Efficiency of InN/InGaN/GaN Intermediate-Band Solar Cell under the Effects of Hydrostatic Pressure, In-Compositions, Built-in-Electric Field, Confinement, and Thickness

This paper presents a thorough numerical investigation focused on optimizing the efficiency of quantum-well intermediate-band solar cells (QW-IBSCs) based on III-nitride materials. The optimization strategy encompasses manipulating confinement potential energy, controlling hydrostatic pressure, adju...

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Bibliographic Details
Published in:Nanomaterials (Basel, Switzerland) Switzerland), 2024-01, Vol.14 (1), p.104
Main Authors: Abboudi, Hassan, El Ghazi, Haddou, En-Nadir, Redouane, Basyooni-M Kabatas, Mohamed A, Jorio, Anouar, Zorkani, Izeddine
Format: Article
Language:English
Subjects:
Alternative energy sources
Analysis
built-in field
Composition
Confinement
Efficiency
Electric fields
Electric properties
Electricity distribution
Electromagnetic absorption
Finite element method
Gallium compounds
Gallium nitrides
Hydrostatic pressure
IBSC
III-nitrides
Indium
Materials science
Mechanical properties
Nanoparticles
Nitrides
Optical properties
Photovoltaic cells
Photovoltaics
Potential energy
Pressure effects
Quantum dots
Quantum wells
Renewable energy
Schrodinger equation
semi-graded potential
Solar batteries
Solar cells
Solar energy
Solar power
Solar power generation
Sustainable energy
Thickness
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Summary:This paper presents a thorough numerical investigation focused on optimizing the efficiency of quantum-well intermediate-band solar cells (QW-IBSCs) based on III-nitride materials. The optimization strategy encompasses manipulating confinement potential energy, controlling hydrostatic pressure, adjusting compositions, and varying thickness. The built-in electric fields in (In, Ga)N alloys and heavy-hole levels are considered to enhance the results' accuracy. The finite element method (FEM) and Python 3.8 are employed to numerically solve the Schrödinger equation within the effective mass theory framework. This study reveals that meticulous design can achieve a theoretical photovoltaic efficiency of quantum-well intermediate-band solar cells (QW-IBSCs) that surpasses the Shockley-Queisser limit. Moreover, reducing the thickness of the layers enhances the light-absorbing capacity and, therefore, contributes to efficiency improvement. Additionally, the shape of the confinement potential significantly influences the device's performance. This work is critical for society, as it represents a significant advancement in sustainable energy solutions, holding the promise of enhancing both the efficiency and accessibility of solar power generation. Consequently, this research stands at the forefront of innovation, offering a tangible and impactful contribution toward a greener and more sustainable energy future.
ISSN:2079-4991
2079-4991
DOI:10.3390/nano14010104