Abstract
In this work four novel donor-acceptor copolymers, PCDTBTDI-DMO, PCDTBTDI-8, P2F-CDTBTDI-DMO and P2F-CDTBTDI-8, were designed and synthesised via Suzuki polymerisation. The first two copolymers consist of 2,7-carbazole flanked by thienyl moieties as the electron donor unit and benzothiadiazole dicarboxylic imide (BTDI) as electron acceptor units. In the structures of P2F-CDTBTDI-DMO and P2F-CDTBTDI-8 copolymers, two fluorine atoms were incorporated at 3,6-positions of 2,7-carbazole to investigate the impact of fluorine upon the optoelectronic, structural and thermal properties of the resulting polymers. P2F-CDTBTDI-8 possesses the highest number average molecular weight (Mn = 24,200 g mol−1) among all the polymers synthesised. PCDTBTDI-DMO and PCDTBTDI-8 show identical optical band gaps of 1.76 eV. However, the optical band gaps of fluorinated copolymers are slightly higher than non-fluorinated counterparts. All polymers have deep-lying highest occupied molecular orbital (HOMO) levels. Changing the alkyl chain substituents on BTDI moieties from linear n-octyl to branched 3,7-dimethyloctyl groups as well as substituting the two hydrogen atoms at 3,6-positions of carbazole unit by fluorine atoms has negligible impact on the HOMO levels of the polymers. Similarly, the lowest unoccupied molecular orbital (LUMO) energy levels are almost comparable for all polymers. Thermogravimetric analysis (TGA) has shown that all polymers have good thermal stability and also confirmed that the fluorinated copolymers have higher thermal stability relative to those non-fluorinated analogues. Powder X-ray diffraction (XRD) studies proved that all polymers have an amorphous nature in the solid state.
Highlights
Due to a significant increase in energy demand, as well as the growing concern regarding the adverse impacts of using fossil energy resources, the necessity for a sustainable and renewable alternate source of energy has gained importance in recent years [1,2,3,4,5]
The results indicate that a change of alkyl chains on benzothiadiazole dicarboxylic imide (BTDI) units from 3,7-dimethyloctyl chains to n-octyl chains does not have any impact on the Eg of the PCDTBTDI-DMO and PCDTBTDI-8, while it has a little impact on the Eg of the fluorinated polymers
Both polymers (P2F-CDTBTDI-DMO and P2F-CDTBTDI-8) have lower Eg compared to the PCffDTBT that was synthesised in the Iraqi group [66]
Summary
Due to a significant increase in energy demand, as well as the growing concern regarding the adverse impacts of using fossil energy resources, the necessity for a sustainable and renewable alternate source of energy has gained importance in recent years [1,2,3,4,5]. The band gap of polycarbazoles can be lowered by copolymerizing 2,7-carbazole moieties with a variety of acceptor units through alternating donor-acceptor (D-A) strategy Based on this strategy, different types of high photovoltaic performance carbazole copolymers have been developed. You and co-workers have designed and synthesised a new acceptor unit, 4,7-di-2-thienyl-5,6-difluoro-2,1,3-benzothiadiazole (DTffBT) It was copolymerized with benzodithiophene (BDT) to build a PBDT-DTffBT copolymer. Developed a new acceptor moiety based on DTBT by substituting one hydrogen atom at 5-position of BT with fluorine atom to construct DTfBT It was copolymerized with alkylthienyl substituted BDT to form PBDT-DTfBT. Bo and co-workers inserted fluorine atoms on the donor unit They reported a novel copolymer poly[3,6-difluoro-9-octyl-9H-2,7-carbazole-alt-5,5-(40 ,70 -di-2-thienyl-50 ,60 -bis(octyloxy)20 ,10 ,30 -benzothiadiazole)] (O-PDFCDTBT) based on 3,6-difluoro-2,7-carbazole flanked by thienyl units and (OR) BT. The result of the present work indicates that copolymerization is a novel approach to synthesizing conductive or alternating polymers with low band gaps and amorphous phases
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