TY - INPR A1 - Wohlgemuth, Matthias A1 - Mitric, Roland T1 - Excitation energy transport in DNA modelled by multi-chromophoric field-induced surface hopping T2 - Physical Chemistry Chemical Physics N2 - Absorption of ultraviolet light is known as a major source of carcinogenic mutations of DNA. The underlying processes of excitation energy dissipation are yet not fully understood. In this work we provide a new and generally applicable route for studying the excitation energy transport in multi-chromophoric complexes at an atomistic level. The surface-hopping approach in the frame of the extended Frenkel exciton model combined with QM/MM techniques allowed us to simulate the photodynamics of the alternating (dAdT)10 : (dAdT)10 double-stranded DNA. In accordance with recent experiments, we find that the excited state decay is multiexponential, involving a long and a short component which are due to two distinct mechanisms: formation of long-lived delocalized excitonic and charge transfer states vs. ultrafast decaying localized states resembling those of the bare nucleobases. Our simulations explain all stages of the ultrafast photodynamics including initial photoexcitation, dynamical evolution out of the Franck-Condon region, excimer formation and nonradiative relaxation to the ground state. KW - Photodynamics KW - DNA Y1 - 2020 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-209467 ET - submitted version ER - TY - INPR A1 - Humeniuk, Alexander A1 - Bužančić, Margarita A1 - Hoche, Joscha A1 - Cerezo, Javier A1 - Mitric, Roland A1 - Santoro, Fabrizio A1 - Bonačić-Koutecky, Vlasta T1 - Predicting fluorescence quantum yields for molecules in solution: A critical assessment of the harmonic approximation and the choice of the lineshape function T2 - The Journal of Chemical Physics N2 - For the rational design of new fluorophores, reliable predictions of fluorescence quantum yields from first principles would be of great help. However, efficient computational approaches for predicting transition rates usually assume that the vibrational structure is harmonic. While the harmonic approximation has been used successfully to predict vibrationally resolved spectra and radiative rates, its reliability for non-radiative rates is much more questionable. Since non-adiabatic transitions convert large amounts of electronic energy into vibrational energy, the highly excited final vibrational states deviate greatly from harmonic oscillator eigenfunctions. We employ a time-dependent formalism to compute radiative and non-radiative rates for transitions and study the dependence on model parameters. For several coumarin dyes we compare different adiabatic and vertical harmonic models (AS, ASF, AH, VG, VGF, VH), in order to dissect the importance of displacements, frequency changes and Duschinsky rotations. In addition we analyze the effect of different broadening functions (Gaussian, Lorentzian or Voigt). Moreover, to assess the qualitative influence of anharmonicity on the internal conversion rate, we develop a simplified anharmonic model. We adress the reliability of these models considering the potential errors introduced by the harmonic approximation and the phenomenological width of the broadening function. KW - fluorescence quantum yield Y1 - 2020 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-199305 UR - https://doi.org/10.1063/1.5143212 N1 - Accepted Manuscript. N1 - This article may be downloaded for personal use only. Any other use requires prior permission of the author and AIP Publishing. This article appeared in A. Humeniuk et al. J. Chem. Phys. 152, 054107 (2020); https://doi.org/10.1063/1.5143212 and may be found at https://doi.org/10.1063/1.5143212. ER - TY - INPR A1 - Titov, Evgenii A1 - Humeniuk, Alexander A1 - Mitric, Roland T1 - Comparison of moving and fixed basis sets for nonadiabatic quantum dynamics at conical intersections T2 - Chemical Physics N2 - We assess the performance of two different types of basis sets for nonadiabatic quantum dynamics at conical intersections. The basis sets of both types are generated using Ehrenfest trajectories of nuclear coherent states. These trajectories can either serve as a moving (time-dependent) basis or be employed to sample a fixed (time-independent) basis. We demonstrate on the example of two-state two-dimensional and three-state five-dimensional models that both basis set types can yield highly accurate results for population transfer at intersections, as compared with reference quantum dynamics. The details of wave packet evolutions are discussed for the case of the two-dimensional model. The fixed basis is found to be superior to the moving one in reproducing nonlocal spreading and maintaining correct shape of the wave packet upon time evolution. Moreover, for the models considered, the fixed basis set outperforms the moving one in terms of computational efficiency. KW - Nonadiabatic quantum dynamics Y1 - 2020 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-199225 UR - https://doi.org/10.1016/j.chemphys.2019.110526 N1 - Submitted version ER - TY - INPR A1 - Lindner, Joachim O. A1 - Sultangaleeva, Karina A1 - Röhr, Merle I. S. A1 - Mitric, Roland T1 - metaFALCON: A program package for automatic sampling of conical intersection seams using multistate metadynamics T2 - Journal of Chemical Theory and Computation N2 - The multistate metadynamics for automatic exploration of conical intersection seams and systematic location of minimum energy crossing points in molecular systems and its implementation into the software package metaFALCON is presented. Based on a locally modified energy gap between two Born–Oppenheimer electronic states as a collective variable, multistate metadynamics trajectories are driven toward an intersection point starting from an arbitrary ground state geometry and are subsequently forced to explore the conical intersection seam landscape. For this purpose, an additional collective variable capable of distinguishing structures within the seam needs to be defined and an additional bias is introduced into the off-diagonal elements of an extended (multistate) electronic Hamiltonian. We demonstrate the performance of the algorithm on the examples of the 1,3-butadiene, benzene, and 9H-adenine molecules, where multiple minimum energy crossing points could be systematically located using the Wiener number or Cremer–Pople parameters as collective variables. Finally, with the example of 9H-adenine, we show that the multistate metadynamics potential can be used to obtain a global picture of a conical intersection seam. Our method can be straightforwardly connected with any ab initio or semiempirical electronic structure theory that provides energies and gradients of the respective electronic states and can serve for systematic elucidation of the role of conical intersections in the photophysics and photochemistry of complex molecular systems, thus complementing nonadiabatic dynamics simulations. KW - Computational Chemistry KW - Metadynamics KW - Hydrogen KW - Hydrocarbons KW - Chemical Structure Y1 - 2019 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-199258 UR - https://doi.org/10.1021/acs.jctc.9b00029 N1 - This document is the Accepted Manuscript version of a Published Work that appeared in final form in Journal of Chemical Theory and Computation, copyright © American Chemical Society after peer review and technical editing by the publisher. To access the final edited and published work see Journal of Chemical Theory and Computation 2019, 15, 6, 3450-3460. https://doi.org/10.1021/acs.jctc.9b00029. ER - TY - INPR A1 - Lisinetskaya, Polina G. A1 - Mitric, Roland T1 - Collective Response in DNA-Stabilized Silver Cluster Assemblies from First-Principles Simulations T2 - The Journal of Physical Chemistry Letters N2 - We investigate fluorescence resonant energy transfer and concurrent electron dynamics in a pair of DNA-stabilized silver clusters. For this purpose we introduce a methodology for the simulation of collective optoelectronic properties of coupled molecular aggregates starting from first-principles quantum chemistry, which can be further applied to a broad range of coupled molecular systems to study their electro-optical response. Our simulations reveal the existence of low-energy coupled excitonic states, which enable ultrafast energy transport between subunits, and give insight into the origin of the fluorescence signal in coupled DNA-stabilized silver clusters, which have been recently experimentally detected. Hence, we demonstrate the possibility of constructing ultrasmall energy transmission lines and optical converters based on these hybrid molecular systems. KW - Metal clusters Y1 - 2019 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-198729 UR - https://doi.org/10.1021/acs.jpclett.9b03136 N1 - This document is the unedited Author’s version of a Submitted Work that was subsequently accepted for publication in Journal of Physical Chemistry A, copyright © American Chemical Society after peer review. To access the final edited and published work see The Journal of Physical Chemistry Letters 2019, 10, 24, 7884-7889. https://doi.org/10.1021/acs.jpclett.9b03136. ER - TY - INPR A1 - Röder, Anja A1 - Petersen, Jens A1 - Issler, Kevin A1 - Fischer, Ingo A1 - Mitric, Roland A1 - Poisson, Lionel T1 - Exploring the Excited-State Dynamics of Hydrocarbon Radicals, Biradicals and Carbenes using Time-Resolved Photoelectron Spectroscopy and Field-Induced Surface Hopping Simulations T2 - The Journal of Physical Chemistry A N2 - Reactive hydrocarbon molecules like radicals, biradicals and carbenes are not only key players in combustion processes and interstellar and atmospheric chemistry, but some of them are also important intermediates in organic synthesis. These systems typically possess many low-lying, strongly coupled electronic states. After light absorption, this leads to rich photodynamics characterized by a complex interplay of nuclear and electronic motion, which is still not comprehensively understood and not easy to investigate both experimentally and theoretically. In order to elucidate trends and contribute to a more general understanding, we here review our recent work on excited-state dynamics of open-shell hydrocarbon species using time-resolved photoelectron spectroscopy and field-induced surface hopping simulations, and report new results on the excited-state dynamics of the tropyl and the 1-methylallyl radical. The different dynamics are compared, and the difficulties and future directions of time-resolved photoelectron spectroscopy and excited state dynamics simulations of open-shell hydrocarbon molecules are discussed. KW - Excited state dynamics KW - Hydrocarbon radicals KW - time-resolved photoelectron spectroscopy KW - field-induced surface hopping Y1 - 2019 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-198734 UR - https://doi.org/10.1021/acs.jpca.9b06346 N1 - This document is the unedited Author’s version of a Submitted Work that was subsequently accepted for publication in Journal of Physical Chemistry A, copyright © American Chemical Society after peer review. To access the final edited and published work see Journal of Physical Chemistry A 2019, 123, 50, 10643-10662. https://doi.org/10.1021/acs.jpca.9b06346. ER - TY - INPR A1 - Titov, Evgenii A1 - Humeniuk, Alexander A1 - Mitric, Roland T1 - Exciton localization in excited-state dynamics of a tetracene trimer: A surface hopping LC-TDDFTB study T2 - Physical Chemistry Chemical Physics N2 - Excitons in the molecular aggregates of chromophores are key participants in important processes such as photosynthesis or the functioning of organic photovoltaic devices. Therefore, the exploration of exciton dynamics is crucial. Here we report on exciton localization during excited-state dynamics of the recently synthesized tetracene trimer [Liu et al., Org. Lett., 2017, 19, 580]. We employ the surface hopping approach to nonadiabatic molecular dynamics in conjunction with the long-range corrected time-dependent density functional tight binding (LC-TDDFTB) method [Humeniuk and Mitrić, Comput. Phys. Commun., 2017, 221, 174]. Utilizing a set of descriptors based on the transition density matrix, we perform comprehensive analysis of exciton dynamics. The obtained results reveal an ultrafast exciton localization to a single tetracene unit of the trimer during excited-state dynamics, along with exciton transfer between units. KW - Exciton dynamics Y1 - 2018 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-198680 UR - https://doi.org/10.1039/C8CP05240A N1 - Accepted Manuscript ER - TY - INPR A1 - Auerhammer, Nina A1 - Schulz, Alexander A1 - Schmiedel, Alexander A1 - Holzapfel, Marco A1 - Hoche, Joscha A1 - Röhr, Merle I. S. A1 - Mitric, Roland A1 - Lambert, Christoph T1 - Dynamic exciton localisation in a pyrene-BODIPY-pyrene dye conjugate T2 - Physical Chemistry Chemical Physics N2 - The photophysics of a molecular triad consisting of a BODIPY dye and two pyrene chromophores attached in 2-position are investigated by steady state and fs-time resolved transient absorption spectroscopy as well as by field induced surface hopping (FISH) simulations. While the steady state measurements indicate moderate chromophore interactions within the triad, the time resolved measurements show upon pyrene excitation a delocalised excited state which localises onto the BODIPY chromophore with a time constant of 0.12 ps. This could either be interpreted as an internal conversion process within the excitonically coupled chromophores or as an energy transfer from the pyrenes to the BODIPY dye. The analysis of FISH-trajectories reveals an oscillatory behaviour where the excitation hops between the pyrene units and the BODIPY dye several times until finally they become localised on the BODIPY chromophore within 100 fs. This is accompanied by an ultrafast nonradiative relaxation within the excitonic manifold mediated by the nonadiabatic coupling. Averaging over an ensemble of trajectories allowed us to simulate the electronic state population dynamics and determine the time constants for the nonradiative transitions that mediate the ultrafast energy transfer and exciton localisation on BODIPY. KW - Exciton localization dynamics Y1 - 2019 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-198718 UR - https://doi.org/10.1039/C9CP00908F N1 - Accepted manuscript ER - TY - JOUR A1 - Verma, Pramod Kumar A1 - Steinbacher, Andreas A1 - Schmiedel, Alexander A1 - Nuernberger, Patrick A1 - Brixner, Tobias T1 - Excited-state intramolecular proton transfer of 2-acetylindan-1,3-dione studied by ultrafast absorption and fluorescence spectroscopy JF - Structural Dynamics N2 - We employ transient absorption from the deep-UV to the visible region and fluorescence upconversion to investigate the photoinduced excited-state intramolecular proton-transfer dynamics in a biologically relevant drug molecule, 2-acetylindan-1,3-dione. The molecule is a ß-diketone which in the electronic ground state exists as exocyclic enol with an intramolecular H-bond. Upon electronic excitation at 300 nm, the first excited state of the exocyclic enol is initially populated, followed by ultrafast proton transfer (≈160 fs) to form the vibrationally hot endocyclic enol. Subsequently, solvent-induced vibrational relaxation takes place (≈10 ps) followed by decay (≈390 ps) to the corresponding ground state. KW - time resolved spectroscopy KW - ground states KW - fluorescence spectra KW - absorption spectra KW - ultraviolet light KW - hydrogen bonding KW - excited states KW - reaction mechanisms KW - fluorescence KW - solvents Y1 - 2016 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-181301 VL - 3 ER - TY - THES A1 - Götz, Sebastian Reinhold T1 - Nonlinear spectroscopy at the diffraction limit: probing ultrafast dynamics with shaped few-cycle laser pulses T1 - Nichtlineare Spektroskopie am Beugungslimit: Untersuchung ultraschneller Dynamiken mit geformten Laserpulsen N2 - An experimental setup for probing ultrafast dynamics at the diffraction limit was developed, characterized and demonstrated in the scope of the thesis, aiming for optical investigations while simultaneously approaching the physical limits on the length and timescale. An overview of this experimental setup was given in Chapter 2, as well as the considerations that led to the selection of the individual components. Broadband laser pulses with a length of 9.3 fs, close to the transform limit of 7.6 fs, were focused in a NA = 1.4 immersion oil objective, to the diffraction limit of below 300 nm (FWHM). The spatial focus shape was characterized with off-resonance gold nanorod scatterers scanned through the focal volume. For further insights into the functionality and limitations of the pulse shaper, its calibration procedure was reviewed. The deviations between designed and experimental pulse shapes were attributed to pulse-shaper artifacts, including voltage-dependent inter-layer as well as intra-layer LCD-pixel crosstalk, Fabry-Pérot-type reflections in the LCD layers, and space-time coupling. A pixel-dependent correction was experimentally carried out, which can be seen as an extension of the initial calibration to all possible voltage combinations of the two LCD layers. The capabilities of the experimental setup were demonstrated in two types of experiments, targeting the nonlinearity of gold (Chapter 3) as well as two-dimensional spectroscopy at micro-structured surfaces (Chapter 4). Investigating thin films, an upper bound for the absolute value for the imaginary part of the nonlinear refractive index of gold could be set to |n′′ 2 (Au)| < 0.6·10−16 m2/W, together with |n′ 2 (Au)| < 1.2·10−16 m2/W as an upper bound for the absolute value of the real part. Finite-difference time-domain simulations on y-shaped gold nanostructures indicated that a phase change of ∆Φ ≥ 0.07 rad between two plasmonic modes would induce a sufficient change in the spatial contrast of emission to the far-field to be visible in the experiment. As the latter could not be observed, this value of ∆Φ was determined as the upper bound for the experimentally induced phase change. An upper bound of 52 GW/cm2 was found for the damage threshold. In Chapter 4, a novel method for nonlinear spectroscopy on surfaces was presented. Termed coherent two-dimensional fluorescence micro-spectroscopy, it is capable of exploring ultrafast dynamics in nanostructures and molecular systems at the diffraction limit. Two-dimensional spectra of spatially isolated hotspots in structured thin films of fluorinated zinc phthalocyanine (F16ZnPc) dye were taken with a 27-step phase-cycling scheme. Observed artifacts in the 2D maps were identified as a consequence from deviations between the desired and the experimental pulse shapes. The optimization procedures described in Chapter 2 successfully suppressed the deviations to a level where the separation from the nonlinear sample response was feasible. The experimental setup and methods developed and presented in the scope of this thesis demonstrate its flexibility and capability to study microscopic systems on surfaces. The systems exemplarily shown are consisting of metal-organic dyes and metallic nanostructures, represent samples currently under research in the growing fields of organic semiconductors and plasmonics. N2 - Ein experimenteller Aufbau zur Untersuchung von ultraschnellen Dynamiken am Beugungslimit wurde in dieser Arbeit entwickelt, charakterisiert und demonstriert. Sie hatte zum Ziel, im Rahmen von optischen Beobachtungen gleichzeitig an die physikalischen Grenzen von Längen- und Zeitskalen zu gehen Es wurde ein Überblick über den verwendeten experimentellen Aufbau gegeben, zusammen mit den Überlegungen, die zur Auswahl der einzelnen Komponenten geführt haben. Für die Pulslänge der spektral breitbandigen Laserpulse wurde auf 9.3 fs gemessen, was nahe an der transformlimitierten Dauer von 7.6 fs liegt. Im beugungslimitierten Fokus eines Immersionsölobjektivs mit einer numerischen Apertur von 1.4 konnte das Licht räumlich auf eine Halbwertsbreite von unter 300 nm komprimiert werden. Der Fokus des Mikroskopobjektivs wurde mit Hilfe der Streuung von nicht resonanten Nanopartikeln aus Gold ausgemessen, indem diese räumlich durch den Fokus gerastert wurden. Zur weiteren Untersuchung des Funktionsumfangs und der Grenzen des benutzten Pulsformers wurde dessen Eichprozedur geprüft. Die Abweichungen zwischen gewünschten und tatsächlich angelegten Pulsformen wurden auf Artefakte des Pulsformers zurückgeführt. Diese Artefakte beinhalten eine spannungsabhängige Beeinflussung der LCD-Pixel sowohl zwischen benachbarten Pixeln einer Schicht als auch zwischen Pixeln unterschiedlicher Schichten. Eine pixelabhängige Korrektur wurde implementiert, die eine Erweiterung der ursprünglichen Kalibrierung auf alle möglichen Spannungskombinationen der LCD-Pixel darstellt. Die Möglichkeiten experimentellen Aufbaus wurden mit zwei Arten von Experimenten demonstriert: Messungen zur Bestimmung des nichtlinearen Brechungsindexes von Gold (Kapitel 3) sowie zweidimensionale Spektroskopie an mikrostrukturierten Oberflächen (Kapitel 4). Für den nichtlinearen Brechungsindexes von Gold konnte an Dünnschichten eine obere Grenze von |n′′ 2 (Au)| < 0.6·10−16 m2/W für den Betrag des Imaginärteils und |n′ 2 (Au)| < 1.2·10−16 m2/W für den Betrag des Realteils festgesetzt werden. Simulationen mit der Finite-Differenzen-Methode an Y-förmige Nanostrukturen aus Gold zeigten, dass eine Phasenänderung von ∆Φ ≥ 0.07 rad zwischen zwei plasmonischen Moden ausreichend für eine experimentell sichtbare Kontraständerung der Fernfeldabstrahlung wäre. Da letztere nicht beobachtet werden konnte, wurde dieser Wert für ∆Φ als obere Grenze für die experimentell eingeführte Phasenänderung festgesetzt. Für die Zerstörschwelle wurde eine obere Grenze von 52 GW/cm2 gefunden. In Kapitel 4, wurde eine neue Methode für nichtlineare Spektroskopie an Oberflächen vorgestellt. Sie trägt den Namen ”Kohärente zweidimensionale Fluoreszenz-Mikrospektroskopie“ und eignet sich zur Untersuchung ultraschneller Dynamiken in Nanostrukturen und molekularen Systemen am Beugungslimit. Es wurden 2D-Spektren von räumlich isolierten Hotspots einer strukturierten Zink-Phthalocyanin (F16ZnPc) Dünnschicht mit 27-fachem Phasecycling aufgenommen. Als Grund für Artefakte in den 2D-Karten wurden Abweichungen zwischen den gewünschten und experimentellen Pulsformen identifiziert. Durch die in Kapitel 2 vorgestellten Optimierungen konnten die Abweichungen allerdings so stark reduziert werden, dass deren Trennung von der nichtlinearen Antwort der Probe möglich wurde. Die Flexibilität und der Funktionsumfang zur Analyse mikroskopischer Systeme der im Rahmen dieser Arbeit entwickelten experimentellen Aufbauten und Methoden wurde demonstriert. Repräsentativ für die wachsenden Forschungsfelder der organischen Halbleiter und der Plasmonik wurden exemplarisch Systeme bestehend aus metall-organischen Farbstoffen und metallischen Nanostrukturen untersucht. KW - Ultrakurzzeitspektroskopie KW - Fluoreszenzspektroskopie KW - Fourier-Spektroskopie KW - Nanostruktur KW - Konfokale Mikroskopie KW - Coherent Multidimensional Spectroscopy KW - Laser Pulse Shaping KW - LCD Pulse Shaper KW - Surface Plasmon KW - Kohärente Multidimensionale Spektroskopie KW - Laserpulsformung KW - LCD Pulsformer KW - Oberflächenplasmon Y1 - 2019 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-192138 ER -