posted on 2017-03-21, 00:00authored byHaijun Bin, Yankang Yang, Zhi-Guo Zhang, Long Ye, Masoud Ghasemi, Shanshan Chen, Yindong Zhang, Chunfeng Zhang, Chenkai Sun, Lingwei Xue, Changduk Yang, Harald Ade, Yongfang Li
In the last two years,
polymer solar cells (PSCs) developed quickly
with n-type organic semiconductor (n-OSs) as acceptor. In contrast, the research progress of nonfullerene
organic solar cells (OSCs) with organic small molecule as donor and
the n-OS as acceptor lags behind. Here, we synthesized
a D–A structured medium bandgap organic small molecule H11 with bithienyl-benzodithiophene (BDTT) as central donor
unit and fluorobenzotriazole as acceptor unit, and achieved a power
conversion efficiency (PCE) of 9.73% for the all organic small molecules
OSCs with H11 as donor and a low bandgap n-OS IDIC as acceptor. A control molecule H12 without
thiophene conjugated side chains on the BDT unit was also synthesized
for investigating the effect of the thiophene conjugated side chains
on the photovoltaic performance of the p-type organic
semiconductors (p-OSs). Compared with H12, the 2D-conjugated H11 with thiophene conjugated side
chains shows intense absorption, low-lying HOMO energy level, higher
hole mobility and ordered bimodal crystallite packing in the blend
films. Moreover, a larger interaction parameter (χ) was observed
in the H11 blends calculated from Hansen solubility parameters
and differential scanning calorimetry measurements. These special
features combined with the complementary absorption of H11 donor and IDIC acceptor resulted in the best PCE of 9.73% for nonfullerene
all small molecule OSCs up to date. Our results indicate that fluorobenzotriazole
based 2D conjugated p-OSs are promising medium bandgap
donors in the nonfullerene OSCs.