A DFT approach toward designing selenophene‐based unfused small molecule acceptors by end‐capped modification for improving the photovoltaic performance of organic solar cells

A DFT approach toward designing selenophene‐based unfused small molecule acceptors by end‐capped modification for improving the photovoltaic performance of organic solar cells

Abstract In this study, we have developed a series of eight non‐fullerene acceptors, constituting A‐D‐A type small molecules named (SS1–SS8) to enlighten the open‐circuit voltage ( V oc ) and the efficacy of pre‐existed SR (reference) molecule. Density functional theory has been adopted to computati...

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Bibliographic Details
Published in:Journal of physical organic chemistry Vol. 37; no. 3
Main Authors: Rukhsar, Jaweria, Waqas, Muhammad, Akhter, Muhamed Salim, Shaban, Mohamed, Al‐Saeedi, Sameerah I., Mahr, Muhammad Shabir, Hasanin, Tamer H. A., Ibrahim, Mahmoud A. A., Alatawi, Naifa S., Khera, Rasheed Ahmad
Format: Journal Article
Language:English
Published: Bognor Regis Wiley Subscription Services, Inc 01-03-2024
Subjects:
Charge transfer
Chloroform
Density functional theory
Dipole moments
Electromagnetic absorption
Optoelectronics
Photovoltaic cells
Red shift
Solar cells
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Summary:Abstract In this study, we have developed a series of eight non‐fullerene acceptors, constituting A‐D‐A type small molecules named (SS1–SS8) to enlighten the open‐circuit voltage ( V oc ) and the efficacy of pre‐existed SR (reference) molecule. Density functional theory has been adopted to computationally assess the optoelectronic features of fabricated molecules with the B3LYP/6‐31G (d, p) level of theory. Several factors like charge transfer, light absorption, binding energy, dipole moment, and reorganization energy are studied. The frontier orbitals analysis revealed that all the newly developed molecules have less bandgap (ranging from 1.97 to 2.22 eV) than SR (2.23 eV). Similarly, these newly engineered molecules also revealed better light absorption by screening remarkable redshift from 676.23 to 789.28 nm than SR (673.83 nm) in chloroform. These molecules have remarkably reduced excitation energy ranging from 1.71 to 1.83 eV than SR 1.84 eV. The exclusive CT analysis is carried out via J61:SS8 complex because of the higher V oc of SS8 (acceptor). Additionally, SS8 has shown the least energy loss, making it a strong contender to be used to develop improved OSCs. Because of the exceptionally improved characteristics, these newly engineered molecules (especially SS8) can be considered potential aspirants for fabricating proficient OSCs.
ISSN:0894-3230
1099-1395
DOI:10.1002/poc.4587