Davydov Splitting and Self-Organization in a Porphyrin Layer Noncovalently Attached to Single Wall Carbon Nanotubes

Géraud Delport; Fabien Vialla; Cyrielle Roquelet; Stéphane Campidelli; Christophe Voisin; Jean Sébastien Lauret

doi:10.1021/acs.nanolett.7b02996

Davydov Splitting and Self-Organization in a Porphyrin Layer Noncovalently Attached to Single Wall Carbon Nanotubes

Géraud Delport
, Fabien Vialla
, Cyrielle Roquelet
, Stéphane Campidelli
, Christophe Voisin
, Jean Sébastien Lauret

Research output: Contribution to journal › Article › peer-review

Abstract

We study the ability of porphyrin molecules to cooperate upon adsorption on the sp² curved surface of carbon nanotube. We discuss the role of the phenyl substituents in the cooperativity of the functionalization reaction. Moreover, a specific spatial organization of the molecules around the nanotube is unveiled through polarization sensitive experiments. Furthermore, we observe an increase of the energy splitting of the porphyrin main transition upon the adsorption on the nanotube. This effect, interpreted as a Davydov splitting, is analyzed quantitatively using a dipole-dipole coupling model. This study demonstrates the ability of porphyrin molecules to create an organized self-assembled layer at the surface of the nanotubes where molecules are electronically coupled together.

Original language	English
Pages (from-to)	6778-6782
Number of pages	5
Journal	Nano Letters
Volume	17
Issue number	11
DOIs	https://doi.org/10.1021/acs.nanolett.7b02996
Publication status	Published - 8 Nov 2017
Externally published	Yes

Keywords

Davydov splitting
Self-assembly
energy transfer
functionalization
hybrid nanomaterials
nanotube
porphyrin

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10.1021/acs.nanolett.7b02996

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title = "Davydov Splitting and Self-Organization in a Porphyrin Layer Noncovalently Attached to Single Wall Carbon Nanotubes",

abstract = "We study the ability of porphyrin molecules to cooperate upon adsorption on the sp2 curved surface of carbon nanotube. We discuss the role of the phenyl substituents in the cooperativity of the functionalization reaction. Moreover, a specific spatial organization of the molecules around the nanotube is unveiled through polarization sensitive experiments. Furthermore, we observe an increase of the energy splitting of the porphyrin main transition upon the adsorption on the nanotube. This effect, interpreted as a Davydov splitting, is analyzed quantitatively using a dipole-dipole coupling model. This study demonstrates the ability of porphyrin molecules to create an organized self-assembled layer at the surface of the nanotubes where molecules are electronically coupled together.",

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AU - Delport, Géraud

AU - Vialla, Fabien

AU - Roquelet, Cyrielle

AU - Campidelli, Stéphane

AU - Voisin, Christophe

AU - Lauret, Jean Sébastien

PY - 2017/11/8

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N2 - We study the ability of porphyrin molecules to cooperate upon adsorption on the sp2 curved surface of carbon nanotube. We discuss the role of the phenyl substituents in the cooperativity of the functionalization reaction. Moreover, a specific spatial organization of the molecules around the nanotube is unveiled through polarization sensitive experiments. Furthermore, we observe an increase of the energy splitting of the porphyrin main transition upon the adsorption on the nanotube. This effect, interpreted as a Davydov splitting, is analyzed quantitatively using a dipole-dipole coupling model. This study demonstrates the ability of porphyrin molecules to create an organized self-assembled layer at the surface of the nanotubes where molecules are electronically coupled together.

AB - We study the ability of porphyrin molecules to cooperate upon adsorption on the sp2 curved surface of carbon nanotube. We discuss the role of the phenyl substituents in the cooperativity of the functionalization reaction. Moreover, a specific spatial organization of the molecules around the nanotube is unveiled through polarization sensitive experiments. Furthermore, we observe an increase of the energy splitting of the porphyrin main transition upon the adsorption on the nanotube. This effect, interpreted as a Davydov splitting, is analyzed quantitatively using a dipole-dipole coupling model. This study demonstrates the ability of porphyrin molecules to create an organized self-assembled layer at the surface of the nanotubes where molecules are electronically coupled together.

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KW - Self-assembly

KW - energy transfer

KW - functionalization

KW - hybrid nanomaterials

KW - nanotube

KW - porphyrin

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Davydov Splitting and Self-Organization in a Porphyrin Layer Noncovalently Attached to Single Wall Carbon Nanotubes

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Keywords

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