Investigating ultrafast two-pulse experiments on single DNQDI fluorophores: A stochastic quantum approach

Giulia Dall'Osto; Emanuele Coccia; Ciro A. Guido; Stefano Corni

doi:10.1039/d0cp02557g

Investigating ultrafast two-pulse experiments on single DNQDI fluorophores: A stochastic quantum approach

Giulia Dall'Osto
, Emanuele Coccia
, Ciro A. Guido
, Stefano Corni

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

Abstract

Ultrafast two-pulse experiments on single molecules are invaluable tools to investigate the microscopic dynamics of a fluorophore. The first pulse generates electronic or vibronic coherence and the second pulse probes the time-evolution of the coherence. A protocol that is able to simulate ultrafast experiments on single molecules is applied in this study. It is based on a coupled quantum-mechanical description of the fluorophore and real-time dynamics of the system vibronic wave packet interacting with an electric field, described by means of the stochastic Schrödinger equation within the Markovian limit. This approach is applied to the DNQDI fluorophore, previously investigated experimentally [D. Brinks et al., Nature, 2010, 465, 905-908]. We find this to be in good agreement with the experimental outcomes and provide microscopic and atomistic interpretation.

Original language	English
Pages (from-to)	16734-16746
Number of pages	13
Journal	Physical Chemistry Chemical Physics
Volume	22
Issue number	29
DOIs	https://doi.org/10.1039/d0cp02557g
Publication status	Published - 7 Aug 2020
Externally published	Yes

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title = "Investigating ultrafast two-pulse experiments on single DNQDI fluorophores: A stochastic quantum approach",

abstract = "Ultrafast two-pulse experiments on single molecules are invaluable tools to investigate the microscopic dynamics of a fluorophore. The first pulse generates electronic or vibronic coherence and the second pulse probes the time-evolution of the coherence. A protocol that is able to simulate ultrafast experiments on single molecules is applied in this study. It is based on a coupled quantum-mechanical description of the fluorophore and real-time dynamics of the system vibronic wave packet interacting with an electric field, described by means of the stochastic Schr{\"o}dinger equation within the Markovian limit. This approach is applied to the DNQDI fluorophore, previously investigated experimentally [D. Brinks et al., Nature, 2010, 465, 905-908]. We find this to be in good agreement with the experimental outcomes and provide microscopic and atomistic interpretation.",

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AU - Dall'Osto, Giulia

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AU - Guido, Ciro A.

AU - Corni, Stefano

PY - 2020/8/7

Y1 - 2020/8/7

N2 - Ultrafast two-pulse experiments on single molecules are invaluable tools to investigate the microscopic dynamics of a fluorophore. The first pulse generates electronic or vibronic coherence and the second pulse probes the time-evolution of the coherence. A protocol that is able to simulate ultrafast experiments on single molecules is applied in this study. It is based on a coupled quantum-mechanical description of the fluorophore and real-time dynamics of the system vibronic wave packet interacting with an electric field, described by means of the stochastic Schrödinger equation within the Markovian limit. This approach is applied to the DNQDI fluorophore, previously investigated experimentally [D. Brinks et al., Nature, 2010, 465, 905-908]. We find this to be in good agreement with the experimental outcomes and provide microscopic and atomistic interpretation.

AB - Ultrafast two-pulse experiments on single molecules are invaluable tools to investigate the microscopic dynamics of a fluorophore. The first pulse generates electronic or vibronic coherence and the second pulse probes the time-evolution of the coherence. A protocol that is able to simulate ultrafast experiments on single molecules is applied in this study. It is based on a coupled quantum-mechanical description of the fluorophore and real-time dynamics of the system vibronic wave packet interacting with an electric field, described by means of the stochastic Schrödinger equation within the Markovian limit. This approach is applied to the DNQDI fluorophore, previously investigated experimentally [D. Brinks et al., Nature, 2010, 465, 905-908]. We find this to be in good agreement with the experimental outcomes and provide microscopic and atomistic interpretation.

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Investigating ultrafast two-pulse experiments on single DNQDI fluorophores: A stochastic quantum approach

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