Collective states of α-sexithiophene chains inside boron nitride nanotubes

arXiv - PHYS - Atomic and Molecular Clusters Pub Date : 2024-08-28 DOI:arxiv-2408.15885

Sabrina Juergensen, Jean-Baptiste Marceau, Chantal Mueller, Eduardo B. Barros, Patryk Kusch, Antonio Setaro, Etienne Gaufrès, Stephanie Reich

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Abstract

Nanotubes align molecules into one dimensional chains creating collective states through the coupling of the molecular transition dipole moments. These collective excitations have strong fluorescence, narrow bandwidth, and shifted emission/absorption energies. We study the optical properties of {\alpha}-sexithiophene chains in boron nitride nanotubes by combining fluorescence with far- and near-field absorption spectroscopy. The inner nanotube diameter determines the number of encapsulated molecular chains. A single chain of {\alpha}-sexithiophene molecules has an optical absorption and emission spectrum that is red-shifted by almost 300 meV compared to the monomer emission, which is much larger than expected from dipole-dipole coupling. The collective state splits into excitation and emission channels with a Stokes shift of 200 meV for chains with two or more files. Our study emphasises the formation of a delocalized collective state through Coulomb coupling of the transition moments that shows a remarkable tuneability in transition energy.

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氮化硼纳米管内 α-噻吩链的集合态

纳米管将分子排列成一维链，通过分子过渡偶极矩的耦合产生集合激发态。这些集合激发具有强荧光、窄带宽和偏移的发射/吸收能量。我们通过将荧光与远场和近场吸收光谱相结合，研究了氮化硼纳米管中{α}-噻吩链的光学特性。纳米管的内径决定了封装分子链的数量。单个{α}-噻吩分子链的光吸收和发射光谱与单体发射光谱相比红移了近300 meV，这比偶极-偶极耦合所预期的要大得多。对于具有两个或更多文件的链，集合态分裂为激发和发射通道，斯托克斯位移为 200 meV。我们的研究强调了通过转换矩的库仑耦合形成的脱局域集合态，它显示了转换能量的显著可调节性。

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arXiv - PHYS - Atomic and Molecular Clusters

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