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Modeling the high-energy electronic state manifold of adenine: Calibration for nonlinear electronic spectroscopy

Pump-probe electronic spectroscopy using femtosecond laser pulses has evolved into a standard tool for tracking ultrafast excited state dynamics. Its two-dimensional (2D) counterpart is becoming an increasingly available and promising technique for resolving many of the limitations of pump-probe cau...

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Published in:	The Journal of chemical physics 2015-06, Vol.142 (21), p.212443-212443
Main Authors:	Nenov, Artur, Giussani, Angelo, Segarra-Martí, Javier, Jaiswal, Vishal K, Rivalta, Ivan, Cerullo, Giulio, Mukamel, Shaul, Garavelli, Marco
Format:	Article
Language:	English
Subjects:	ADENINES ATOMIC AND MOLECULAR PHYSICS CALCULATION METHODS CHEMICAL BONDS Chemical Sciences Computation Computer simulation DIPOLE MOMENTS ELECTRON SPECTROSCOPY Electron states Electronic spectra EXCITED STATES Femtosecond pulses Field theory FLUCTUATIONS INORGANIC, ORGANIC, PHYSICAL AND ANALYTICAL CHEMISTRY LASER RADIATION LIFETIME MONOMERS NONLINEAR PROBLEMS or physical chemistry Organic chemistry Parameter estimation PERTURBATION THEORY Physics PROBES REDUCTION SELF-CONSISTENT FIELD Spectroscopy Spectrum analysis Theoretical and Theory Tracking TRANSIENTS TWO-DIMENSIONAL SYSTEMS ULTRAVIOLET RADIATION Ultraviolet spectra Variation
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description	Pump-probe electronic spectroscopy using femtosecond laser pulses has evolved into a standard tool for tracking ultrafast excited state dynamics. Its two-dimensional (2D) counterpart is becoming an increasingly available and promising technique for resolving many of the limitations of pump-probe caused by spectral congestion. The ability to simulate pump-probe and 2D spectra from ab initio computations would allow one to link mechanistic observables like molecular motions and the making/breaking of chemical bonds to experimental observables like excited state lifetimes and quantum yields. From a theoretical standpoint, the characterization of the electronic transitions in the visible (Vis)/ultraviolet (UV), which are excited via the interaction of a molecular system with the incoming pump/probe pulses, translates into the determination of a computationally challenging number of excited states (going over 100) even for small/medium sized systems. A protocol is therefore required to evaluate the fluctuations of spectral properties like transition energies and dipole moments as a function of the computational parameters and to estimate the effect of these fluctuations on the transient spectral appearance. In the present contribution such a protocol is presented within the framework of complete and restricted active space self-consistent field theory and its second-order perturbation theory extensions. The electronic excited states of adenine have been carefully characterized through a previously presented computational recipe [Nenov et al., Comput. Theor. Chem. 1040-1041, 295-303 (2014)]. A wise reduction of the level of theory has then been performed in order to obtain a computationally less demanding approach that is still able to reproduce the characteristic features of the reference data. Foreseeing the potentiality of 2D electronic spectroscopy to track polynucleotide ground and excited state dynamics, and in particular its expected ability to provide conformational dependent fingerprints in dimeric systems, the performances of the selected reduced level of calculations have been tested in the construction of 2D electronic spectra for the in vacuo adenine monomer and the unstacked adenine homodimer, thereby exciting the Lb/La transitions with the pump pulse pair and probing in the Vis to near ultraviolet spectral window.
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Its two-dimensional (2D) counterpart is becoming an increasingly available and promising technique for resolving many of the limitations of pump-probe caused by spectral congestion. The ability to simulate pump-probe and 2D spectra from ab initio computations would allow one to link mechanistic observables like molecular motions and the making/breaking of chemical bonds to experimental observables like excited state lifetimes and quantum yields. From a theoretical standpoint, the characterization of the electronic transitions in the visible (Vis)/ultraviolet (UV), which are excited via the interaction of a molecular system with the incoming pump/probe pulses, translates into the determination of a computationally challenging number of excited states (going over 100) even for small/medium sized systems. A protocol is therefore required to evaluate the fluctuations of spectral properties like transition energies and dipole moments as a function of the computational parameters and to estimate the effect of these fluctuations on the transient spectral appearance. In the present contribution such a protocol is presented within the framework of complete and restricted active space self-consistent field theory and its second-order perturbation theory extensions. The electronic excited states of adenine have been carefully characterized through a previously presented computational recipe [Nenov et al., Comput. Theor. Chem. 1040-1041, 295-303 (2014)]. A wise reduction of the level of theory has then been performed in order to obtain a computationally less demanding approach that is still able to reproduce the characteristic features of the reference data. 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Its two-dimensional (2D) counterpart is becoming an increasingly available and promising technique for resolving many of the limitations of pump-probe caused by spectral congestion. The ability to simulate pump-probe and 2D spectra from ab initio computations would allow one to link mechanistic observables like molecular motions and the making/breaking of chemical bonds to experimental observables like excited state lifetimes and quantum yields. From a theoretical standpoint, the characterization of the electronic transitions in the visible (Vis)/ultraviolet (UV), which are excited via the interaction of a molecular system with the incoming pump/probe pulses, translates into the determination of a computationally challenging number of excited states (going over 100) even for small/medium sized systems. A protocol is therefore required to evaluate the fluctuations of spectral properties like transition energies and dipole moments as a function of the computational parameters and to estimate the effect of these fluctuations on the transient spectral appearance. In the present contribution such a protocol is presented within the framework of complete and restricted active space self-consistent field theory and its second-order perturbation theory extensions. The electronic excited states of adenine have been carefully characterized through a previously presented computational recipe [Nenov et al., Comput. Theor. Chem. 1040-1041, 295-303 (2014)]. A wise reduction of the level of theory has then been performed in order to obtain a computationally less demanding approach that is still able to reproduce the characteristic features of the reference data. Foreseeing the potentiality of 2D electronic spectroscopy to track polynucleotide ground and excited state dynamics, and in particular its expected ability to provide conformational dependent fingerprints in dimeric systems, the performances of the selected reduced level of calculations have been tested in the construction of 2D electronic spectra for the in vacuo adenine monomer and the unstacked adenine homodimer, thereby exciting the Lb/La transitions with the pump pulse pair and probing in the Vis to near ultraviolet spectral window.</abstract><cop>United States</cop><pub>American Institute of Physics</pub><pmid>26049463</pmid><doi>10.1063/1.4921016</doi><tpages>1</tpages><orcidid>https://orcid.org/0000-0002-2076-3406</orcidid><orcidid>https://orcid.org/0000-0002-6015-3135</orcidid><orcidid>https://orcid.org/0000-0002-1208-602X</orcidid><orcidid>https://orcid.org/0000-0002-0796-289X</orcidid><oa>free_for_read</oa></addata></record>
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subjects	ADENINES ATOMIC AND MOLECULAR PHYSICS CALCULATION METHODS CHEMICAL BONDS Chemical Sciences Computation Computer simulation DIPOLE MOMENTS ELECTRON SPECTROSCOPY Electron states Electronic spectra EXCITED STATES Femtosecond pulses Field theory FLUCTUATIONS INORGANIC, ORGANIC, PHYSICAL AND ANALYTICAL CHEMISTRY LASER RADIATION LIFETIME MONOMERS NONLINEAR PROBLEMS or physical chemistry Organic chemistry Parameter estimation PERTURBATION THEORY Physics PROBES REDUCTION SELF-CONSISTENT FIELD Spectroscopy Spectrum analysis Theoretical and Theory Tracking TRANSIENTS TWO-DIMENSIONAL SYSTEMS ULTRAVIOLET RADIATION Ultraviolet spectra Variation
title	Modeling the high-energy electronic state manifold of adenine: Calibration for nonlinear electronic spectroscopy
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