<p>Electronic chirality within single molecules constitutes an intriguing phenomenon in quantum chemistry, whose inducing mechanism however remains underexplored. Here, we report a distinct formation mechanism for electronic chirality in CuPc molecules adsorbed on bilayer graphene on highly oriented pyrolytic graphite, as incurred via twisted <i>π</i>-<i>π</i> stacking. Scanning tunneling microscopy measurements unveil that CuPc molecules exhibit prominent chirality in morphology at low biases, but restore their D<sub>4h</sub> symmetry at large biases, demonstrating the chirality is electronic origin. With tip manipulations, the two enantiomers of CuPc can be reversibly switched. Density functional theory calculations reveal that the electronic chirality arises from <i>π</i>-<i>π</i> hybridization between CuPc and graphene, leading to asymmetric charge distribution. The chiral configuration is determined by adsorption sites and rotation angles relative to graphene, in agreement with experimental observations. This work uncovers a <i>π</i>-<i>π</i> hybridization mechanism for driving electronic chirality, providing a platform for designing chiral molecular electronic devices.</p>

错误:搜索内容不能为空,请输入英文关键词
错误:关键词超出字数限制,请精简
高级检索

Molecular electronic chirality in copper phthalocyanine induced via twisted π-π stacking on bilayer graphene

  • Hao-Jun Qin,
  • Rui-Jing Sun,
  • Jia-Jun Liu,
  • Wen-Ao Liao,
  • Dao-Bo Wang,
  • Jiang Yu,
  • Tian-Hao Leng,
  • Chao-Fei Liu,
  • Wen-Hao Zhang,
  • Ying-Shuang Fu

摘要

Electronic chirality within single molecules constitutes an intriguing phenomenon in quantum chemistry, whose inducing mechanism however remains underexplored. Here, we report a distinct formation mechanism for electronic chirality in CuPc molecules adsorbed on bilayer graphene on highly oriented pyrolytic graphite, as incurred via twisted π-π stacking. Scanning tunneling microscopy measurements unveil that CuPc molecules exhibit prominent chirality in morphology at low biases, but restore their D4h symmetry at large biases, demonstrating the chirality is electronic origin. With tip manipulations, the two enantiomers of CuPc can be reversibly switched. Density functional theory calculations reveal that the electronic chirality arises from π-π hybridization between CuPc and graphene, leading to asymmetric charge distribution. The chiral configuration is determined by adsorption sites and rotation angles relative to graphene, in agreement with experimental observations. This work uncovers a π-π hybridization mechanism for driving electronic chirality, providing a platform for designing chiral molecular electronic devices.