New [pi]-Conjugated Materials Based on Furylenevinylene Candidate for Organic Solar Cells Application: A DFT Study

The specific properties of organic-conjugated molecules and polymers are of great importance since they have become the most promising materials for the optoelectronic device technology such as solar cells. The use of low band gap materials is a viable method for better harvesting of the solar spect...

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Bibliographic Details
Published in:Orbital : The Electronic Journal of Chemistry 2015-10, Vol.7 (4), p.327
Main Authors: Alamy, Aziz El, Amine, Amina, Bouachrine, Mohamed
Format: Article
Language:English
Subjects:
Solar cells
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Summary:The specific properties of organic-conjugated molecules and polymers are of great importance since they have become the most promising materials for the optoelectronic device technology such as solar cells. The use of low band gap materials is a viable method for better harvesting of the solar spectrum and increasing its efficiency. The control of the parameters of these materials is a research issue of ongoing interest. In this work, a quantum chemical investigation was performed to explore the optical and electronic properties of a series of different compounds based on furylenevinylene. Different electron side groups were introduced to investigate their effects on the electronic structure. The theoretical knowledge of the highest occupied molecular orbital (HOMO) and lowest unoccupied molecular orbital (LUMO) energy levels of the components is basic in studying organic solar cells; so the HOMO, LUMO, Gap energy and open circuit voltage ([V.sub.oc]) of the studied compounds have been calculated and reported. These properties suggest that these materials behave as good candidate for organic solar cells. Keywords: [pi]-conjugated molecules; furan; furylenevinylene; organic solar cells; DFT; low band gap; optoelectronic properties
ISSN:1984-6428
1984-6428
DOI:10.17807/orbital.v7i4.763