激子
材料科学
扫描隧道显微镜
量子隧道
离子键合
分子
共发射极
光电子学
发光
电介质
库仑
电子结构
电子
分子物理学
原子物理学
纳米技术
凝聚态物理
化学
物理
离子
有机化学
量子力学
作者
Jiří Doležal,Pingo Mutombo,Dana Nachtigallová,Pavel Jelı́nek,Pablo Merino,Martin Švec
出处
期刊:ACS Nano
[American Chemical Society]
日期:2020-06-15
卷期号:14 (7): 8931-8938
被引量:18
标识
DOI:10.1021/acsnano.0c03730
摘要
The ability to control the emission from single-molecule quantum emitters is an important step toward their implementation in optoelectronic technology. Phthalocyanine and derived metal complexes on thin insulating layers studied by scanning tunneling microscope-induced luminescence (STML) offer an excellent playground for tuning their excitonic and electronic states by Coulomb interaction and to showcase their high environmental sensitivity. Copper phthalocyanine (CuPc) has an open-shell electronic structure, and its lowest-energy exciton is a doublet, which brings interesting prospects in its application for optospintronic devices. Here, we demonstrate that the excitonic state of a single CuPc molecule can be reproducibly switched by atomic-scale manipulations permitting precise positioning of the molecule on the NaCl ionic crystal lattice. Using a combination of STML, AFM, and ab initio calculations, we show the modulation of electronic and optical bandgaps and the exciton binding energy in CuPc by tens of meV. We explain this effect by spatially dependent Coulomb interaction occurring at the molecule-insulator interface, which tunes the local dielectric environment of the emitter.
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