Key Laboratory of Organosilicon Chemistry and Material Technology of Ministry of Education, Hangzhou Normal University , Hangzhou 310012, People's Republic of China.
CAS Key Laboratory of Standardization and Measurement for Nanotechnology, CAS Center for Excellence in Nanoscience, National Center for Nanoscience and Technology (NCNST) , Beijing 100190, People's Republic of China.
ACS Nano. 2017 Nov 28;11(11):11701-11713. doi: 10.1021/acsnano.7b06961. Epub 2017 Nov 15.
Electron-rich (donor) and electron-deficient (acceptor) units to construct donor-acceptor (D-A) conjugated macrocycles were investigated to elucidate their interactions with electron-deficient fullerene. Triphenylamine and 4,7-bisthienyl-2,1,3-benzothiadiazole were alternately linked through acetylene, as the donor and acceptor units, respectively, for pentagonal 3B2A and hexagonal 4B2A macrocycles. As detected by scanning tunneling microscopy, both D-A macrocycles were found to form an interesting concentration-controlled nanoporous monolayer on highly oriented pyrolytic graphite, which could effectively capture fullerene. Significantly, the fullerene filling was cavity-size-dependent with only one C or PCBM molecule accommodated by 3B2A, while two were accommodated by 4B2A. Density functional theory calculations were also utilized to gain insight into the host-guest systems and indicted that the S···π contact is responsible for stabilizing these host-guest systems. Owing to the ellipsoidal shape of C, C molecules are standing or lying in molecular cavities depending on the energy optimization. For the 3B2A/PCBM blended film, PCBM was intercalated into the cavity formed by the macrocycle 3B2A and provided excellent power conversion efficiency despite the broad band gap (2.1 eV) of 3B2A. This study of D-A macrocycles incorporating fullerene provides insights into the interaction mechanism and electronic structure in the host-guest complexes. More importantly, this is a representative example using D-A macrocycles as a donor to match with the spherical fullerene acceptor for photovoltaic applications, which offer a good approach to achieve molecular scale p-n junctions for substantially enhanced efficiencies of organic solar cells through replacing linear polymer donors by cyclic conjugated oligomers.
电子富(供体)和电子缺(受体)单元被用于构建供体-受体(D-A)共轭大环,以阐明它们与缺电子富勒烯的相互作用。三苯胺和 4,7-双噻吩基-2,1,3-苯并噻二唑通过乙炔交替连接,分别作为供体和受体单元,用于构建五重 3B2A 和六重 4B2A 大环。扫描隧道显微镜检测表明,两种 D-A 大环都在高度取向的热解石墨上形成了有趣的浓度控制的纳米多孔单层,可有效捕获富勒烯。重要的是,富勒烯的填充与空腔大小有关,3B2A 只能容纳一个 C 或 PCBM 分子,而 4B2A 则可以容纳两个。密度泛函理论计算也被用于深入了解主客体体系,并表明 S···π 接触是稳定这些主客体体系的原因。由于 C 的椭圆形形状,C 分子在分子腔中或站立或躺下,这取决于能量优化。对于 3B2A/PCBM 共混膜,PCBM 被插入大环 3B2A 形成的空腔中,尽管 3B2A 的带宽隙(2.1 eV)较宽,但仍提供了出色的功率转换效率。这项包含富勒烯的 D-A 大环研究提供了对主客体复合物中相互作用机制和电子结构的深入了解。更重要的是,这是一个使用 D-A 大环作为供体与球形富勒烯受体相匹配的代表性例子,用于光伏应用,通过用环状共轭寡聚物代替线性聚合物供体,为有机太阳能电池的效率提高提供了一种很好的方法,从而实现分子级的 p-n 结。
