Synthesis and properties of novel fluorinated subnaphthalocyanines for organic photovoltaic cells

Abstract: Novel fluorinated subnaphthalocyanine derivatives were newly designed and synthesized as donor materials for low molecular organic photovoltaic cells using fullerene as an acceptor. They were designed to have the low-lying HOMO energy levels for improvement of open circuit voltage without any expense of short-circuit current density. The HOMO/LUMO energy levels of hexafluoro-, heptafluoro-, dodecafluoro-, tridecafluoro-and the parent subnaphthalocyanine estimated based on the photoelectron spectroscopy were-5.… Show more

“…Takao et al also treated the two products with AgBF 4 to substitute the axial chloride with a uoride. 20 In addition to the synthesis of 'standard' BsubNcs from 2,3-dicyanonaphthalene, Kobayashi et al also prepared chiral analogs of BsubNcs via the reaction of 1,2-dicyanonaphthalene with BCl 3 to form chiral Cl-1,2-BsubNc and subsequent phenoxy derivatives. 21 A review of the above mentioned studies (see Table S1 †) reveals that detailed characterization of the BsubNcs is generally limited.…”

“…1 H and 19 F NMR data are reported (both numerically and graphically) along with HRMS data by Takao et al (entry 6). 20 BsubPcs have recently been applied as functional materials in organic electronic devices most notably in organic photovoltaic devices (OPVs). [22][23][24][25][26][27][28][29][30][31] Although the recent efforts of our group 29,30 and others [25][26][27][28]31 have shown that a variety of BsubPcs can have application in OPVs, the majority of the applications have focused on the use of the prototypical derivative Cl-BsubPc.…”

The mixed alloyed chemical composition of chloro-(chloro)_n-boron subnaphthalocyanines dictates their physical properties and performance in organic photovoltaic devices

“…Takao et al also treated the two products with AgBF 4 to substitute the axial chloride with a uoride. 20 In addition to the synthesis of 'standard' BsubNcs from 2,3-dicyanonaphthalene, Kobayashi et al also prepared chiral analogs of BsubNcs via the reaction of 1,2-dicyanonaphthalene with BCl 3 to form chiral Cl-1,2-BsubNc and subsequent phenoxy derivatives. 21 A review of the above mentioned studies (see Table S1 †) reveals that detailed characterization of the BsubNcs is generally limited.…”

“…1 H and 19 F NMR data are reported (both numerically and graphically) along with HRMS data by Takao et al (entry 6). 20 BsubPcs have recently been applied as functional materials in organic electronic devices most notably in organic photovoltaic devices (OPVs). [22][23][24][25][26][27][28][29][30][31] Although the recent efforts of our group 29,30 and others [25][26][27][28]31 have shown that a variety of BsubPcs can have application in OPVs, the majority of the applications have focused on the use of the prototypical derivative Cl-BsubPc.…”

The mixed alloyed chemical composition of chloro-(chloro)_n-boron subnaphthalocyanines dictates their physical properties and performance in organic photovoltaic devices

“…The voltage generated by the organic photovoltaic cell, VOC, is related to the energy gap between the HOMO energy level of the donor and the LUMO energy level of the acceptor materials [21,22], so that control of the HOMO/LUMO energy levels of the electron donors and acceptors is important to optimize the performance of OPVs. We also reported that the HOMO/LUMO energy levels of organic active layers can be controlled by introducing appropriate polar substituents to fullerenes [23] and subphthalocyanines [24].…”

p-n interface stabilization of planar heterojunction organic photovoltaics by an ethyleneoxy side chain of methanofullerenes

“…Chlorosubphthalocyanines possess a peculiar conical structure, which provides them with relatively high solubility and low tendency for aggregation [4]. These subphthalocyanines have been utilized in many fields such as organic photovoltaics (OPV) [5,6], chemical sensors [7], organic light-emitting diodes (OLEDs) [8], organic thin film transistors (OTFTs) [9], supramolecular building blocks for molecular cages [10], solar cells [11,12] and non-linear optics [13].…”

Synthesis of novel dimeric subphthalocyanines via azide-alkyne Huisgen 1,3-dipolar cycloaddition and palladiumcatalyzed Glaser–Hay coupling reactions