Your search keyword '"Schinke, Reinhard"' showing total 232 results

1. On the right track of flood planning policy? Land uptake in Central-European floodplains (1990–2018)

Author

Dolejš, Martin, Raška, Pavel, Kohnová, Silvia, Schinke, Reinhard, Warachowska, Weronika, Thaler, Thomas, and Kočický, Dušan

Published

2022

2. Carbon dioxide photolysis from 150 to 210 nm: Singlet and triplet channel dynamics, UV-spectrum, and isotope effects

Author

Schmidt, Johan A., Johnson, Matthew S., and Schinke, Reinhard

Published

2013

3. State-to-State Quantum Dynamics of O + O₂ Isotope Exchange Reactions Reveals Nonstatistical Behavior at Atmospheric Conditions

Author

Sun, Zhigang, Liu, Lan, Lin, Shi Ying, Schinke, Reinhard, Guo, Hua, Zhang, Dong H., and Zare, Richard N.

Published

2010

4. High groundwater levels: Processes, consequences, and management.

Author

Becker, Bernhard, Reichel, Frank, Bachmann, Daniel, and Schinke, Reinhard

Subjects

WATER table, GROUNDWATER management, HYDRAULIC engineering, FLOOD forecasting, RAINFALL, FLOODS, GROUNDWATER

Abstract

In recent years, the issue of high groundwater levels has caught attention. Unfavorable consequences of high groundwater levels are especially damage to buildings, infrastructure, and the environment. Processes that lead to high groundwater levels are hydrological (heavy or extended rainfall and flood events), or anthropogenic (reduced groundwater extractions, interaction with sewer networks, hydraulic engineering measures, structural interventions in the water balance, and mining activities). Several different map products have been prepared for the information of inhabitants and for planning purposes, and also methods for damage and risk analysis related to high groundwater levels have been developed. Groundwater management measures and structural measures are available to reduce the risk related to high groundwater levels. An operational management system could be combined from existing components, but operational forecasting systems for high groundwater levels are—different to flood forecasting systems—not yet common practice. A better understanding of the processes and the development of integrated approaches for modeling, design, planning, forecasting, and warning, as well as improvement of interdisciplinary collaboration between different organizations, are recommendations for the future. This article is categorized under:Engineering Water > Engineering WaterWater and Life > Conservation, Management, and AwarenessScience of Water > Hydrological ProcessesScience of Water > Water Extremes [ABSTRACT FROM AUTHOR]

Published

2022

5. Learning from and for rare floods in Dresden – how public officials interpret damage simulation results at the building type level

Author

Hutter Gerard and Schinke Reinhard

Subjects

Environmental sciences, GE1-350

Abstract

Public officials in Dresden are concerned about learning from and for rare flood events like the Elbe river flood in August 2002. This is interesting because research on individual as well as organizational learning from rare events indicates that this kind of learning faces significant difficulties (e.g., overestimation of rare events for decision-making based on “emotionalized event experience”). Up to now, only little is known what and how public officials in Dresden specifically learn from and for rare floods. Therefore, the paper follows an exploratory purpose in line with principles of qualitative social research. Firstly, the paper explores dealing with rare floods with reference to a conceptual framework that highlights relations between regulative, normative, and cognitive institutions on the one hand and learning of public officials on the other. Secondly, it adopts a single case study design in Dresden with embedded sub-cases that are defined with reference to organizations of FRM. The case study shows, among others, that regulations like the Floods Directive are important for justifying FRM with regard to rare flood events which is less obvious than it sounds. However, public officials display different interpretations of the term “rare flood event”, for instance, in the context of analysing the consequences of floods on the building stock. Furthermore, the case study findings indicate that public officials may follow alternative approaches to sustain commitment in the context of rare flood events (systematic versus pragmatic approach).

Published

2016

6. Relationship between mode specific and thermal unimolecular rate constants for HOCl --> OH + Cl dissociation

Author

Song, Kihyung, Hase, William L., Sun, Lipeng, Grebenshchikov, S. Yu., and Schinke, Reinhard

Subjects

Chlorine -- Chemical properties, Chemical equations -- Research, Dissociation -- Research, Chemicals, plastics and rubber industries

Abstract

The occurrence of HOCI --> OH + CI dissociation due to highly mode-specific resonance rates is observed. The use of these resonance rates to calculate the HOCI --> OH + CI unimolecular rate constant as a function of temperature and pressure is described and it is found that the state-specificity makes the pressure-dependent rates significantly lower than the RRKM rates in the intermediate pressure regime.

Published

2002

7. Periodic orbits and vibrational wave functions for DCP: nonlinear resonances in isotopically substituted molecules

Author

Farantos, Stavros C., Beck, Christian, and Schinke, Reinhard

Published

1998

8. Nonexponential unimolecular decay of jet-cooled NO(sub 2): comparison of time-resolved measurements and quantum mechanical calculations

Author

Kirmse, Bernd, Abel, Bernd, Schwarzer, Dirk, Grebenshchikov, Sergy Yu, and Schinke, Reinhard

Subjects

Surface energy -- Analysis, Nitrogen dioxide -- Atomic properties, Quantum theory -- Research, Chemicals, plastics and rubber industries

Abstract

The time-resolved measurements for the dissociative decay of NO(sub 2) are presented in its ground electronic state using pump laser pulses with durations of ca. 650fs. The main experimental result is the observation of nonexponential decay, which was pronounced at very low excess energies close to the dissociation threshold.

Published

2000

9. Investigation of loosely bound states of NO(sub 2) just below the first dissociation threshold

Author

Delon,Antoine, Reiche, Florian, Grebenshchikov, Sergy Yu, Schinke, Reinhard, and Abel, Bernd

Subjects

Binding energy -- Analysis, Nitrogen dioxide -- Atomic properties, Dissociation -- Analysis, Chemicals, plastics and rubber industries

Abstract

The loosely bound states of jet cooled NO(sub 2) below the first dissociation threshold D(sub 0) with binding energies E(sub b) between 0.8 and 59.3 cm(super -1) are investigated using pulsed VIS/UV optical double resonance spectroscopy. The result stated that smaller the binding energy, the closer to fire No transitions is the excitation spectrum from the loosely bound states of NO(sub 2) to some unknown excited states.

Published

2000

10. Perspective on “Semiclassical theory of atom–diatom collisions: path integrals and the classical S matrix”: Miller WH (1970) J Chem Phys 53: 1949–1959

Author

Schinke, Reinhard

Published

2000

11. Theory of molecular bound states including Σ–Π vibronic interaction

Author

Poluyanov, Leonid and Schinke, Reinhard

Published

2003

12. Product angular distributions in the ultraviolet photodissociation of N2O.

Author

McBane, George C. and Schinke, Reinhard

Subjects

*ANGULAR distribution (Nuclear physics), *PHOTODISSOCIATION, *NITROUS oxide, *ABSORPTION, *PHYSICAL & theoretical chemistry

Abstract

The angular distribution of products from the ultraviolet photodissociation of nitrous oxide yielding O(1D) and N2(X Σg+1) was investigated using classical trajectory calculations. The calculations modeled absorption only to the 2 1A′ electronic state but used surface-hopping techniques to model nonadiabatic transitions to the ground electronic state late in the dissociation. Observed values of the anisotropy parameter β, which decrease as the product N2 rotational quantum number j increases, could be well reproduced. The relatively low observed β values arise principally from nonaxial recoil due to the very strong bending forces present in the excited state. In the main part of the product rotational distribution near 203 nm, an unusual dynamical effect produces the decrease in β with increasing j; nonaxial recoil effects remain approximately constant while higher j product molecules arise from parent molecules that had their transition dipole moments aligned more closely along the molecular axis. In both low and high j tails of the rotational distribution, the variations in β with j are caused by changes in the extent of nonaxial recoil. In the high-j tail, additional torque present on the ground state potential energy surface following nonadiabatic transitions causes both the additional rotational excitation and the lower β values. [ABSTRACT FROM AUTHOR]

Published

2012

13. Non-linear dynamics of the photodissociation of nitrous oxide: Equilibrium points, periodic orbits, and transition states.

Author

Mauguiere, Frederic, Farantos, Stavros C., Suarez, Jaime, and Schinke, Reinhard

Subjects

PHOTODISSOCIATION, MOLECULAR dynamics, NITROUS oxide, CHEMICAL equilibrium, PHASE transitions, ULTRAVIOLET spectroscopy, ELECTRONIC excitation, POTENTIAL energy surfaces, BIFURCATION theory, NONLINEAR mechanics, PHASE space

Abstract

The diffuse vibrational bands, observed in the ultraviolet photodissociation spectrum of nitrous oxide by exciting the molecule in the first 1A′ state, have recently been attributed to resonances localized mainly in the NN stretch and bend degrees of freedom. To further investigate the origin of this localization, fundamental families of periodic orbits emanating from several stationary points of the 1A′ potential energy surface and bifurcations of them are computed. We demonstrate that center-saddle bifurcations of periodic orbits are the main mechanism for creating stable regions in phase space that can support the partial trapping of the wave packet, and thus they explain the observed spectra. A non-linear mechanical methodology, which involves the calculation of equilibria, periodic orbits, and transition states in normal form coordinates, is applied for an in detail exploration of phase space. The fingerprints of the phase space structures in the quantum world are identified by solving the time dependent Schrödinger equation and calculating autocorrelation functions. This demonstrates that different reaction channels could be controlled if exact knowledge of the phase space structure is available to guide the initial excitation of the molecule. [ABSTRACT FROM AUTHOR]

Published

2011

14. Photodissociation of ozone in the Hartley band: Product state and angular distributions.

Author

McBane, George C., Nguyen, Luan T., and Schinke, Reinhard

Abstract

Product state properties from the photodissociation of ozone in the ultraviolet Hartley band are investigated by trajectory surface-hopping calculations. The diabatic B and R state potential energy and coupling surfaces of Schinke and McBane [J. Chem. Phys. 132, 044305 (2010)] are employed. The properties computed include rotational and vibrational distributions in both the singlet and triplet channels, the total internal energy distribution in the triplet channel, and the photodissociation anisotropy parameter β in the singlet channel. A method for computing β from trajectories computed in internal Jacobi coordinates is described. In the singlet channel, the vibrational distribution is in good agreement with the experimental results. The observed increase in β with increasing photolysis wavelength is reproduced by the calculations and is attributed to the effects of the bending potential on the B state late in the fragmentation. The computed β values are too high with respect to experiment, and the peaks jmax of the singlet-channel rotational distributions are too low; these discrepancies are attributed to a too steep bending potential at long O-O distances. In the triplet channel, the main part of the internal energy distribution is described well by the calculations, although the detailed structures observed in the experiment are not reproduced. The experimental rotational distributions are well reproduced, although the maxima appear at slightly too high j. The triplet state product energy distributions are shown to depend largely on the distribution of hopping points onto the R state surface. A Landau-Zener model constructed as a function of the O2 bond distance provides a good physical description of the two-state dynamics. The high internal energy O2 products that cannot be attributed to the excitation of the Herzberg states remain unexplained. [ABSTRACT FROM AUTHOR]

Published

2010

15. Energies and spatial features for the rotationless bound states of 4He3+(2Σg+): A cationic core from helium cluster ionization.

Author

Scifoni, Emanuele, Gianturco, Franco A., Grebenshchikov, Sergy Yu., and Schinke, Reinhard

Subjects

BOUND states, HELIUM ions, POTENTIAL energy surfaces, ANGULAR momentum (Mechanics), WAVE functions, EIGENVALUES

Abstract

Ab initio quantum calculations have been carried out on the helium ionic trimer. The potential energy surface is accurately fitted, especially in the vicinity of the three equivalent minima. The spectrum of bound states for the zero angular momentum is computed and analyzed in detail. Energies and wave functions reveal several interesting features related to the fact that He3+ represents one of the few homonuclear ionic trimers that are linear in their ground vibrational state. At low energies, the triply degenerate eigenfunctions are localized at the potential minimum. With growing excitation energy, however, the wave functions exhibit stronger spatial delocalization. [ABSTRACT FROM AUTHOR]

Published

2006

16. Recombination of ozone via the chaperon mechanism.

Author

Ivanov, Mikhail V. and Schinke, Reinhard

Subjects

*OZONE, *CHEMICAL reagents, *POTENTIAL energy surfaces, *QUANTUM chemistry, *PHYSICAL & theoretical chemistry, *QUANTUM theory

Abstract

The recombination of ozone via the chaperon mechanism, i.e., ArO+O2→Ar+O3 and ArO2+O→Ar+O3, is studied by means of classical trajectories and a pairwise additive Ar-O3 potential energy surface. The recombination rate coefficient has a strong temperature dependence, which approximately can be described by T -n with n≈3. It is negligible for temperatures above 700 K or so, but it becomes important for low temperatures. The calculations unambiguously affirm the conclusions of Hippler et al. [J. Chem. Phys. 93, 6560 (1990)] and Luther et al. [Phys. Chem. Chem. Phys. 7, 2764 (2005)] that the chaperon mechanism makes a sizable contribution to the recombination of O3 at room temperature and below. The dependence of the chaperon recombination rate coefficient on the isotopomer, studied for two different isotope combinations, is only in rough qualitative agreement with the experimental data. The oxygen atom isotope exchange reaction involving ArO and ArO2 van der Waals complexes is also investigated; the weak binding of O or O2 to Ar has only a small effect. [ABSTRACT FROM AUTHOR]

Published

2006

17. Temperature dependent energy transfer in Ar–O3 collisions.

Author

Ivanov, Mikhail V. and Schinke, Reinhard

Subjects

*ENERGY transfer, *ENERGY storage, *TRANSPORT theory, *GASES, *OXYGEN, *CHEMICAL reagents, *NOBLE gases

Abstract

The energy transfer between argon atoms and ozone complexes O3*, excited in the region of the dissociation threshold, is calculated for fixed temperatures (100 K≤T≤2500 K) using classical trajectories. The internal energy of ozone is resolved in terms of vibrational and rotational energies. For all temperatures, energy flows from O3* to Ar. The vibrational energy transfer, relative to kBT, is very small below 500 K, but gradually increases towards high temperatures. The relative rotational energy transfer, on the other hand, monotonously decreases with T; around 1100 K it falls below the relative vibrational energy transfer. Thermally averaged cross sections for vibrational and rotational energy transfers are also calculated. The implications for the stabilization of ozone complexes in the energy transfer model are discussed. [ABSTRACT FROM AUTHOR]

Published

2005

18. The effect of zero-point energy differences on the isotope dependence of the formation of ozone: A classical trajectory study.

Author

Schinke, Reinhard and Fleurat-Lessard, Paul

Subjects

*ISOTOPES, *OZONE, *FRAGMENTATION reactions, *POTENTIAL energy surfaces, *TRAJECTORY optimization, *QUANTUM chemistry

Abstract

The effect of zero-point energy differences (ΔZPE) between the possible fragmentation channels of highly excited O3 complexes on the isotope dependence of the formation of ozone is investigated by means of classical trajectory calculations and a strong-collision model. ΔZPE is incorporated in the calculations in a phenomenological way by adjusting the potential energy surface in the product channels so that the correct exothermicities and endothermicities are matched. The model contains two parameters, the frequency of stabilizing collisions ω and an energy dependent parameter Δdamp, which favors the lower energies in the Maxwell–Boltzmann distribution. The stabilization frequency is used to adjust the pressure dependence of the absolute formation rate while Δdamp is utilized to control its isotope dependence. The calculations for several isotope combinations of oxygen atoms show a clear dependence of relative formation rates on ΔZPE. The results are similar to those of Gao and Marcus [J. Chem. Phys. 116, 137 (2002)] obtained within a statistical model. In particular, like in the statistical approach an ad hoc parameter η≈1.14, which effectively reduces the formation rates of the symmetric ABA ozone molecules, has to be introduced in order to obtain good agreement with the measured relative rates of Janssen et al. [Phys. Chem. Chem. Phys. 3, 4718 (2001)]. The temperature dependence of the recombination rate is also addressed. [ABSTRACT FROM AUTHOR]

Published

2005

19. The Huggins band of ozone: A theoretical analysis.

Author

Qu, Zheng-Wang, Zhu, Hui, Grebenshchikov, Sergy Yu., Schinke, Reinhard, and Farantos, Stavros C.

Subjects

OZONE, DYNAMICS, POTENTIAL energy surfaces, QUANTUM chemistry, PHYSICS, INVESTIGATIONS

Abstract

The Huggins band of ozone is investigated by means of dynamics calculations using a new (diabatic) potential energy surface for the 3 1A′(1B2) state. The good overall agreement of the calculated spectrum of vibrational energies and intensities with the experimental spectrum, especially at low to intermediate excitation energies, is considered as evidence that the Huggins band is due to the two Cs potential wells of the 1B2 state rather than the single C2v well of the 2 1A′(1A1) state. The vibrational assignment of the “cold bands,” based on the nodal structure of wave functions, on the whole supports the most recent experimental assignment [J. Chem. Phys. 115, 9311 (2001)]. The quantum mechanical spectrum is analyzed in terms of classical periodic orbits and the structure of the classical phase space.© 2004 American Institute of Physics. [ABSTRACT FROM AUTHOR]

Published

2004

20. The transition-state region of the O(3P)+O2(3Σg-) potential energy surface.

Author

Schinke, Reinhard and Fleurat-Lessard, Paul

Subjects

*ELECTRONIC structure, *ENERGY-band theory of solids, *OZONE, *OXYGEN, *QUANTUM chemistry, *POTENTIAL energy surfaces

Abstract

New electronic structure calculations for the transition-state region of the lowest ozone potential energy surface are reported. A two-dimensional potential energy surface in the asymptotic channel is calculated with the O2 bond distance being fixed. The calculations are performed at the multireference average quadratic coupled cluster level of theory using full-valence complete active space self-consistent field wave functions and the augmented correlation consistent polarized V6Z atomic basis set. The general shape of the potential energy surface as predicted in earlier studies, that is, a narrow transition state below the O+O2 asymptote, is confirmed by the present calculations. The transition state is 181 cm-1 below the asymptote and 72 cm-1 above the van der Waals–like minimum. The changes in the O+O2→O3* capture cross section and rate constant when the new potential energy surface is employed are investigated by means of classical trajectory calculations. © 2004 American Institute of Physics. [ABSTRACT FROM AUTHOR]

Published

2004

21. Resonance spectrum and dissociation dynamics of ozone in the 3B2 electronically excited state: Experiment and theory.

Author

Deppe, Sabine F., Wachsmuth, Uwe, Abel, Bernd, Bittererová, Martina, Grebenshchikov, Sergy Yu., Siebert, Rüdiger, and Schinke, Reinhard

Subjects

RESONANCE, ELECTRONICS, POTENTIAL energy surfaces, QUANTUM chemistry, DISSOCIATION (Chemistry), PHYSICAL sciences

Abstract

The rovibrational spectrum assigned to the low-lying 3B2 electronic state of ozone is measured with intracavity laser absorption spectroscopy. The experimental results are interpreted by means of quantum dynamical calculations on a global ab initio potential energy surface. The observed spectrum is shown to originate from the vibrational ground state in the local minimum of the 3B2 potential. The spectrum of short-lived resonance states in this local minimum is analyzed. Additionally, the global minimum of the surface is shown to lie in the dissociation channel in the van der Waals region. This region supports a short sequence of weakly bound vibrational states. © 2004 American Institute of Physics. [ABSTRACT FROM AUTHOR]

Published

2004

22. Intra- and intermolecular energy transfer in highly excited ozone complexes.

Author

Ivanov, Mikhail V., Grebenshchikov, Sergy Yu., and Schinke, Reinhard

Subjects

OZONE, COMPLEX compounds, ENERGY transfer, DEGREES of freedom, ARGON, ATOMS

Abstract

The energy transfer of highly excited ozone molecules is investigated by means of classical trajectories. Both intramolecular energy redistribution and the intermolecular energy transfer in collisions with argon atoms are considered. The sign and magnitude of the intramolecular energy flow between the vibrational and the rotational degrees of freedom crucially depend on the projection Ka of the total angular momentum of ozone on the body-fixed a axis. The intermolecular energy transfer in single collisions between O3 and Ar is dominated by transfer of the rotational energy. In accordance with previous theoretical predictions, the direct vibrational de-excitation is exceedingly small. Vibration–rotation relaxation in multiple Ar+O3 collisions is also studied. It is found that the relaxation proceeds in two clearly distinguishable steps: (1) During the time between collisions, the vibrational degrees of freedom are “cooled” by transfer of energy to rotation; even at low pressure equilibration of the internal energy is slow compared to the time between collisions. (2) In collisions, mainly the rotational modes are “cool” by energy transfer to argon. © 2004 American Institute of Physics. [ABSTRACT FROM AUTHOR]

Published

2004

23. Semiclassical dynamics of the van der Waals states in O3(X 1A1).

Author

Joyeux, Marc, Schinke, Reinhard, and Grebenshchikov, Sergy Yu.

Subjects

*VAN der Waals forces, *OZONE, *VIBRATIONAL spectra, *QUANTUM theory, *WAVE functions, *ION recombination

Abstract

We present the analysis and the semiclassical quantization of the van der Waals states of ozone in the ground electronic state X 1A1. Progressions of these states dominate the spectrum of O3 at threshold. Periodic orbits are used to perform assignment and quantization of the vibrational states. Semiclassical quantization is numerically accurate despite the fact that the classical phase space is chaotic while the nodal patterns of the quantum mechanical wave functions are regular. The lifetimes of recombination of the van der Waals states into the “normal” ozone are also discussed. © 2004 American Institute of Physics. [ABSTRACT FROM AUTHOR]

Published

2004

24. Semiclassical dynamics of the van der Waals states in O3(X 1A1).

Author

Joyeux, Marc, Schinke, Reinhard, and Grebenshchikov, Sergy Yu.

Subjects

VAN der Waals forces, OZONE, VIBRATIONAL spectra, QUANTUM theory, WAVE functions, ION recombination

Abstract

We present the analysis and the semiclassical quantization of the van der Waals states of ozone in the ground electronic state X 1A1. Progressions of these states dominate the spectrum of O3 at threshold. Periodic orbits are used to perform assignment and quantization of the vibrational states. Semiclassical quantization is numerically accurate despite the fact that the classical phase space is chaotic while the nodal patterns of the quantum mechanical wave functions are regular. The lifetimes of recombination of the van der Waals states into the “normal” ozone are also discussed. © 2004 American Institute of Physics. [ABSTRACT FROM AUTHOR]

Published

2004

25. The Huggins band of ozone: Unambiguous electronic and vibrational assignment.

Author

Zheng-Wang Qu, Hui Zhu, Tashiro, Motomichi, Schinke, Reinhard, and Farantos, Stavros C.

Subjects

OZONE, ULTRAVIOLET radiation, WAVE functions, SPECTRUM analysis, ABSORPTION spectra

Abstract

The Huggins band of ozone is investigated by means of exact dynamics calculations using a new (diabatic) potential energy surface for the 1B2 state. The remarkable agreement with the measured spectrum strongly suggests that the Huggins band is due to the two Cs potential wells of the 1B2 state. The vibrational assignment, based on the nodal structure of wave functions, supports the most recent experimental assignment. © 2004 American Institute of Physics. [ABSTRACT FROM AUTHOR]

Published

2004

26. The effect of spin–orbit coupling in complex forming O([sup 3]P) +O[sub 2] collisions.

Author

Tashiro, Motomichi and Schinke, Reinhard

Subjects

*SPIN excitations, *COUPLING constants, *COLLISIONS (Nuclear physics), *EXCHANGE reactions, *OXYGEN

Abstract

The effect of spin–orbit coupling on O([sup 3]P)+O[sub 2]([sup 3]Σ[sub g][sup -]) collisions is investigated for J=0 using time-dependent wave packets. The probability of forming O[sub 3] complexes, which is important for understanding the atom exchange reaction mechanism, is calculated in two different ways. The first approach follows the standard treatment in that only the reactive ground electronic state is included. In the second approach all 27 states correlating with O([sup 3]P)+O[sub 2]([sup 3]Σ[sub g][sup -]) and the nonadiabatic transitions induced by spin–orbit coupling are taken into account; all the excited electronic states are repulsive and thus do not lead to complex formation if nonadiabatic transitions are neglected. The required nine diabatic potential energy surfaces (not including spin–orbit coupling) for the electronic states 1 [sup s]A[sup ′], 2 [sup s]A[sup ′], and [sup s]A[sup ″] (s=1, 3, and 5) are constructed by high-level electronic structure calculations in the asymptotic O+O[sub 2] channel with the O[sub 2] bond length being fixed. The two sets of calculations show that spin–orbit coupling is not an important effect. The probability for forming ozone complexes when the oxygen atom is initially in the excited fine structure state O([sup 3]P[sub j=1]) state is only 10% of that for the lowest state O([sup 3]P[sub j=2]), and it is below 1% for O([sup 3]P[sub j=0]). The single-surface calculation, with the excited states phenomenologically taken into account by a statistical factor, gives a rather accurate value for the thermally averaged complex formation rate coefficient. © 2003 American Institute of Physics. [ABSTRACT FROM AUTHOR]

Published

2003

27. van der Waals states in ozone and their influence on the threshold spectrum of O[sub 3](X [sup 1]A[sub 1]). I. Bound states.

Author

Grebenshchikov, Sergy Yu., Schinke, Reinhard, Fleurat-Lessard, Paul, and Marc Joyeux

Subjects

*OZONE, *POTENTIAL energy surfaces, *DISSOCIATION (Chemistry), *ISOTOPES

Abstract

Threshold spectra of several isotopomers of ozone are studied using accurate quantum mechanical calculations and an ab initio potential energy surface. Shallow van der Waals minima in the dissociation channels, separated from the deep main wells by an 80 cm[sup -1] high barrier, are shown to accommodate long progressions of assignable states. As a result, dense vibrational spectrum of ozone near dissociation is dominated by van der Waals-type states for all studied isotope compositions. © 2003 American Institute of Physics. [ABSTRACT FROM AUTHOR]

Published

2003

28. Isotope dependence of the O+O[sub 2] exchange reaction: Experiment and theory.

Author

Fleurat-Lessard, Paul, Grebenshchikov, S. Yu., Schinke, Reinhard, Janssen, Christof, and Krankowsky, Dieter

Subjects

EXCHANGE reactions, OZONE, ISOTOPES

Abstract

The isotope dependence of the O+O[sub 2] exchange reaction is investigated by means of kinetic experiments and classical trajectory calculations on an accurate potential energy surface. The measurements confirm the previously reported negative temperature dependence and yield the rate coefficients for both the exothermic [sup 18]O+[sup 16]O[sub 2]→[sup 18]O[sup 16]O+[sup 16]O and the endothermic [sup 16]O+[sup 18]O[sub 2]→[sup 16]O[sup 18]O+[sup 18]O reaction between 233 and 353 K: k[sub 8]=(3.4±0.6)×10[sup -12] (300 K/T)[sup 1.1±0.5] cm[sup 3] s[sup -1] and k[sub 6]=(2.7±0.4)×10[sup -12] (300 K/T)[sup 0.9±0.5] cm[sup 3] s[sup -1]. In addition, the ratio of these two rates, R, has been measured with comparatively higher precision. It is 1.27±0.04 at 300 K and also shows a distinct negative temperature dependence. Four types of classical trajectory calculations are performed in order to interpret the experimental result. They differ by the way in which the quantum mechanical zero-point energy of the reactants and the differences of zero-point energies between reactants and products, ΔE[sub ZPE]≈±22 cm[sup -1], are phenomenologically incorporated. Only calculations which account for ΔE[sub ZPE] are successful in reproducing the temperature dependence of R. This emphasizes that ΔE[sub ZPE] is an important factor in low-temperature ozone kinetics. At energies slightly above threshold a dynamical effect is found which additionally favors the exothermic over the endothermic reaction. © 2003 American Institute of Physics. [ABSTRACT FROM AUTHOR]

Published

2003

29. The vibrational spectrum of cyclic ozone.

Author

Siebert, Rüdiger and Schinke, Reinhard

Subjects

*VIBRATIONAL spectra, *OZONE, *ELECTRONIC structure, *MOLECULAR spectroscopy, *QUANTUM chemistry

Abstract

We discuss the vibrational spectrum of rotationless cyclic ozone, i.e., ozone in the so-called ring minimum of the ground electronic state. The bound state calculations utilize the ab initio potential energy surface constructed by Siebert et al. on the basis of high-level electronic structure calculations [J. Chem. Phys. 116, 9749 (2002)]. The spectrum is qualitatively similar to that of H[SUP+,SUB3], except that the energy spacing between the states belonging to the same polyad [ν[SUB1], ν[SUB2]] is much smaller; ν[SUB1] is the breathing mode and ν[SUB2] is the doubly degenerate bending mode. [ABSTRACT FROM AUTHOR]

Published

2003

30. Formation of ozone: Metastable states and anomalous isotope effect.

Author

Babikov, Dmitri, Kendrick, Brian K., Walker, Robert B., Pack, Russell T, Fleurat-Lesard, Paul, and Schinke, Reinhard

Subjects

ISOTOPES, OZONE, ENERGY transfer, ATOMS

Abstract

A clear explanation for an anomalous isotope effect in ozone formation is given in terms of the energy transfer mechanism, where the metastable states of ozone are formed first, and then stabilized by collisions with other atoms. Unusual nonstatistical properties of metastable states spectra discovered earlier [J. Chem. Phys. 118, 6298 (2003)] are incorporated into the kinetics model, where different metastable states are treated as different species, and the stabilization step is treated approximately. The population of the ozone metastable states builds up and decays through three possible O[SUB2] + O channels. When different isotopes of oxygen are involved the three channels become open at different energies because of the differences in the quantum zero-point-energies (ΔZPE) of the different O[SUB2] molecules. The spectrum of metastable states is anomalously dense below the DZPE threshold and these states are accessible only from the lower entrance channel. Also, these low-lying metastable states are stabilized very efficiently (by collisions with third body) because they are energetically close to the bound O[SUB3] states. Such processes significantly enhance the formation rates of ozone isotopologues through the lower channels over the formation rates through the upper channels. Numerical results obtained for J = 0 give isotope effects in the right direction and of the right order of magnitude. Consideration of J>0 should improve the comparison with experiment. [ABSTRACT FROM AUTHOR]

Published

2003

31. NO[sub 2]: Global potential energy surfaces of the ground (1 [sup 2]A[sub 1]) and the first excited (1 [sup 2]B[sub 2]) electronic states.

Author

Kurkal, Vandana, Fleurat-Lessard, Paul, and Schinke, Reinhard

Subjects

POTENTIAL energy surfaces, ENERGY levels (Quantum mechanics), QUANTUM theory, NUCLEAR physics

Abstract

Global ab initio potential energy surfaces for the ground (1 [SUP2]A[SUB1]) and the first excited (1 [SUP2]B[SUB2]) electronic states of NO[SUB2] are presented. The calculations are performed at a multireference configuration interaction level with the correlation consistent quadruple zeta atomic basis set of Dunning (cc-pVQZ). A total of about 5000 ab initio points were calculated. The dissociation energy corresponding to NO[SUB2])→ NO + O and other features of the surfaces are found to be in close agreement with experimental values. The adiabatic ground and the first excited electronic states form a conical intersection and have been diabatized to form two coupled diabatic surfaces. Quantum dynamics calculations are performed to obtain the fundamental frequencies and the energies of low lying bound states. Comparison of bound state energies with experimental values show good agreement. [ABSTRACT FROM AUTHOR]

Published

2003

32. The bound state spectrum of HOBr up to the dissociation limit: Evolution of saddle-node bifurcations.

Author

Azzam, Tarek, Schinke, Reinhard, Farantos, Stavros C., Joyeux, Marc, and Peterson, Kirk A.

Subjects

*POTENTIAL energy surfaces, *BOUND states, *RESONANCE, *BIFURCATION theory, *DISSOCIATION (Chemistry)

Abstract

Based on an accurate potential energy surface [J. Chem. Phys. 113, 4598 (2000)] we calculated ca. 700 bound state energies and wave functions of nonrotating HOBr using the filter-diagonalization method. Similar to HOCl, a 1:2 anharmonic resonance between the HOBr bending and the OBr stretching mode determines the general structure of the level spectrum. One of the results of this resonance is a saddle-node bifurcation at which a new class of states (''dissociation states'') comes into existence, which advance along the HO-Br dissociation path. Because the resonance condition at low energies is better fulfilled for HOBr, the bifurcation occurs at considerably lower energies than for HOCl. The results of the quantum mechanical calculations are interpreted in terms of classical periodic orbits (continuation/bifurcation diagram) and a semiclassical analysis based on a spectroscopic Hamiltonian, which is fitted to the exact energy levels and also taking into account the wave functions. [ABSTRACT FROM AUTHOR]

Published

2003

33. Metastable states of ozone calculated on an accurate potential energy surface.

Author

Babikov, Dmitri, Kendrick, Brian K., Walker, Robert B., T Pack, Russell, Fleurat-Lesard, Paul, and Schinke, Reinhard

Subjects

POTENTIAL energy surfaces, OZONE

Abstract

A new potential energy surface for ozone is developed. It is based on high level ab initio data and includes an accurate description of the barrier region. Full quantum reactive scattering calculations using a coupled channel approach and hyperspherical coordinates are performed on this surface for various isotopic compositions of ozone. Collision lifetimes are obtained over a wide energy range, which gives the spectrum of rovibrational metastable states (scattering resonances). This spectrum is discovered to be very nonstatistical. The spectrum of resonances is dense below the isotopic zero-point-energy threshold and sparse above it. This feature is explained by the opening of additional dissociation channels at higher energies. This behavior is a general quantum mechanical effect that should occur in other triatomic molecules. [ABSTRACT FROM AUTHOR]

Published

2003

34. Theoretical investigation of the temperature dependence of the O+O[sub 2] exchange reaction.

Author

Fleurat-Lessard, Paul, Grebenshchikov, Sergy Yu., Siebert, Rüdiger, Schinke, Reinhard, and Halberstadt, Nadine

Subjects

EXCHANGE reactions, POTENTIAL energy surfaces, SURFACE chemistry

Abstract

The exchange reaction [sup 16]O+[sup 18]O[sub 2]→[sup 16]O[sup 18]O+[sup 18]O and, in particular, its dependence on the transition state region is investigated by classical trajectories on three potential energy surfaces, all based on high-level electronic structure calculations. The first one is the original potential recently constructed by Siebert, Schinke, and Bittererová [Phys. Chem. Chem. Phys. 3, 1795 (2001)]; it has a very small barrier above the O + O[sup 2] asymptote. The second potential is a modification of the first one in that the transition state region is adjusted according to new electronic structure calculations on higher levels of theory; it has a small barrier below the asymptote. The third potential is obtained by artificially removing this barrier. The variation of the exchange reaction cross section with collision energy and the magnitude of the thermal rate constant at and below room temperature depend drastically on the shape of the potential at intermediate distances. The second potential, which is believed to represent the transition state structure of the true ground-state potential of ozone best, yields a reaction rate for room temperature that is about a factor of three smaller than the experimental rate. The neglect of nonadiabatic transitions between the several electronic states in the entrance channel may explain this discrepancy. The very slight negative temperature dependence found in the calculations is caused by the strong decrease of the reaction cross section with the initial rotational excitation of the oxygen molecule. Statistical calculations give poor agreement with the classical energy and initial-state dependent cross sections. Nevertheless, the statistical thermal rates are in fair agreement with the classical ones, because the overestimation of the cross sections for low j's and the underestimation for high j's partly compensate. [ABSTRACT FROM AUTHOR]

Published

2003

35. Resonances in S[sub N]2 reactions: Two-mode quantum calculations for Cl[sup -]+CH[sub 3]Br on a coupled-cluster potential energy surface.

Author

Schmatz, Stefan, Botschwina, Peter, Hauschildt, Jan, and Schinke, Reinhard

Subjects

NUCLEOPHILIC reactions, POTENTIAL energy surfaces, QUANTUM chemistry

Abstract

An effective two-dimensional potential energy surface has been constructed for the S[sub N]2 reaction Cl[sup -]+CH[sub 3]Br→ClCH[sub 3]+Br[sup -] from coupled-cluster calculations with a large basis set. In the quantum dynamics calculations Radau coordinates were employed to describe the Cl-C and C-Br stretching modes. Making use of the filter diagonalization method and an optical potential, bound states as well as resonance states up to energies far above the dissociation threshold have been calculated. The resonance widths fluctuate over several orders of magnitude. In addition to a majority of Feshbach-type resonances there are also exceedingly long-lived shape resonances, which can only decay by tunneling. Owing to a smaller width of the potential barrier and a larger density of states, tunneling through the barrier is more important for Cl[sup -] + CH[sub 3]Br than for Cl[sup -] + CH[sub 3]Cl despite the larger total mass of this system. Excitation of the C-Br stretching vibration enhances the tunneling probability of the entrance channel complex. [ABSTRACT FROM AUTHOR]

Published

2002

36. The asymptotic region of the potential energy surfaces relevant for the O([sup 3]P)+O[sub 2](X [sup 3]Σ[sub g][sup -])⇋O[sub 3] reaction.

Author

Rosmus, Pavel, Palmieri, Paolo, and Schinke, Reinhard

Subjects

POTENTIAL energy surfaces, ASYMPTOTES, OZONE

Abstract

The potential energy functions for all states of ozone correlating with the lowest O(³P) +O[sub 2](X³Σ[sup -][sub g]) asymptote have been calculated in the asymptotic region employing correlated electronic wave functions. For linear ozone, the [sup s]Σ states (s = 1, 3, and 5) lie above the corresponding [sup s]Π states. For bent geometries the H states split into Renner-Teller components with A' and A' symmetry, respectively. While the ¹Π and ³Π states lead to bent-bent Renner-Teller pairs, the [sup 5]Π state gives rise to a linear/linear pair of states. The different spin multiplets emerging from the H states cross for valence angles around 160° and the ¹A' component becomes the lowest one. The matrix elements of the spin-orbit operator have also been calculated. They are dominated by the atomic ³p contributions and their dependence on the mutual orientation of the O[sub 2] molecule and the O atom is small. In the regions where the states correlating to the linear [sup 1,3,5]Π states cross, i.e., for valence angles between 150° and 180° and close to 90°, the mixing among the singlet, triplet, and quintet states is strong and the electron spin quantum number is no longer a good quantum number. [ABSTRACT FROM AUTHOR]

Published

2002

37. The vibrational energies of ozone up to the dissociation threshold: Dynamics calculations on an accurate potential energy surface.

Author

Siebert, Ru¨diger, Fleurat-Lessard, Paul, Schinke, Reinhard, Bittererova´, Martina, and Farantos, S. C.

Subjects

POTENTIAL energy surfaces, OZONE, ELECTRONIC structure

Abstract

We present an ab initio potential energy surface for the ground electronic state of ozone. It is global, i.e., it covers the three identical C[sub 2v] (open) minima, the D[sub 3h] (ring) minimum, as well as the O([sup 3]P) + O[sub 2]([sup 3]σ[sup -, sub g]) dissociation threshold. The electronic structure calculations are performed at the multireference configuration interaction level with complete active space self-consistent-field reference functions and correlation consistent polarized quadruple zeta atomic basis functions. Two of the O-O bond distances, R[sub 1] and R[sub 2], and the O-O-O bending angle are varied on a regular grid (ca. 5000 points with R[sub 1]≥R[sub 2]). An analytical representation is obtained by a three-dimensional cubic spline. The calculated potential energy surface has a tiny dissociation barrier and a shallow van der Waals minimum in the exit channel. The ring minimum is separated from the three open minima by a high potential barrier and therefore presumably does not influence the low-temperature kinetics. The dissociation energy is reproduced up to 90% of the experimental value. All bound states of nonrotating ozone up to more than 99% of the dissociation energy are calculated using the filter diagonalization technique and employing Jacobi coordinates. The three lowest transition energies for [sup 16]O[sub 3] are 1101.9 cm[sup -1] (1103.14 cm[sup -1]), 698.5 cm[sup -1] (700.93 cm[sup -1]), and 1043.9 cm[sup -1] (1042.14 cm[sup -1]) for the symmetric stretch, the bending, and the antisymmetric stretch modes, respectively; the numbers in parentheses are the experimental values. The root-mean-square error for all measured transition energies for [sup 16]O[sub 3] is only 5 cm[sup -1]. The comparison is equally favorable for all other isotopomers, for which experimental frequencies are available. The assignment is made in terms of normal modes, despite the observation that with increasing energy an increasing number of states... [ABSTRACT FROM AUTHOR]

Published

2002

38. The unimolecular dissociation of HCO. V. Mixings between resonance states.

Author

Brandt-Pollmann, Ulrich, Weiß, Jan, and Schinke, Reinhard

Subjects

DISSOCIATION (Chemistry), UNIMOLECULAR reactions

Abstract

The unimolecular dissociation of HCO in its ground electronic state is considered. By performing calculations (filter diagonalization, absorbing potential) for nonzero angular momentum quantum numbers, it is demonstrated how mixings with near-by ”background“ states affect the linewidths of the narrower resonance states. This explains qualitatively the theoretically as well as experimentally observed behavior of the linewidth as a function of the vibrational quantum numbers. [ABSTRACT FROM AUTHOR]

Published

2001

39. On the [formula omitted] internal conversion in the photodissociation of HNCO

Author

Klossika, Jörg-Joachim, Flöthmann, Heiner, Schinke, Reinhard, and Bittererová, Martina

Published

1999

40. Renner–Teller induced predissociation of HNO(A˜ [sup 1]A[sup ″]): Rotational-state dependent linewidths of quasibound states.

Author

Weiß, Jan and Schinke, Reinhard

Subjects

*ELECTRONIC structure, *DISSOCIATION (Chemistry)

Abstract

The predissociation dynamics in the A˜ [sup 1]A[sup ″] electronic state of HNO is investigated. The quantum mechanical dynamics calculations take into account the Renner–Teller (or electronic Coriolis) coupling with the electronic ground state X˜ [sup 1]A[sup ′], which appears to be the dominant decay mechanism for the quasi-bound vibrational states in the A˜ [sup 1]A[sup ″] upper state. All three internal vibrational degrees of freedom are incorporated and two ab initio potential energy surfaces are used. The linewidths, Γ, are directly calculated by the filter diagonalization method and an absorbing optical potential in the exit channel. They are generally small (∼1 cm[sup -1]) and increase with excitation of the bending mode (bent-to-bent transition). On average, Γ increases with K, the a-axis rotational quantum number. However, for some vibrational states the linewidth shows a non-monotonic behavior with K, which is the result of mixing with highly excited vibrational levels in the continuum of the ground electronic state. This effect is even more striking, when the total angular momentum quantum number J is varied: In some cases, the linewidth exhibits a pronounced resonancelike behavior as function of J. The agreement with recent experimental spectroscopic data is satisfactory. The calculated linewidths are of the same order (within a factor of 2 or so) as the experimental ones. However, because the two ab initio potential energy surfaces do not reproduce sufficiently well the X˜–A˜ excitation energies, the resonancelike effects are not quantitatively described. Potential energy surfaces with considerably higher accuracy are required. © 2001 American Institute of Physics. [ABSTRACT FROM AUTHOR]

Published

2001

41. Unimolecular dissociation of HOCl: unexpectedly broad distribution of rate constants

Author

Hauschildt, J., Weiß, J., Beck, C., Grebenshchikov, S.Yu., Düren, R., Schinke, Reinhard, and Koput, J.

Published

1999

42. Absorption cross section of ozone isotopologues calculated with the multiconfiguration time-dependent Hartree (MCTDH) method: I. The Hartley and Huggins bands

Author

Ndengue, Steve Alexandre, Gatti, Fabien, Schinke, Reinhard, Meyer, Hans-Dieter, and Jost, Remy

Subjects

Dipole moments -- Analysis, Isotopes -- Chemical properties, Isotopes -- Optical properties, Ozone -- Chemical properties, Ozone -- Thermal properties, Photolysis -- Analysis, Chemicals, plastics and rubber industries

Published

2010

43. Energy localization in molecules, bifurcation phenomena, and their spectroscopic signatures: the global view

Author

Farantos, Stavros C., Schinke, Reinhard, Hua Guo, and Joyeux, Marc

Subjects

Acetylene -- Chemical properties, Acetylene -- Spectra, Hamiltonian systems -- Research, Infrared radiation -- Usage, Methylene compounds -- Chemical properties, Methylene compounds -- Structure, Oxidases -- Chemical properties, Oxidases -- Spectra, Vibrational spectra -- Usage, Chemistry

Published

2009

44. Time-dependent density functional theory study of the electronic excitation spectra of chlorophyllide a and pheophorbide a in solvents

Author

Qu, Zheng-wang, Zhu, Hui, May, Volkhard, and Schinke, Reinhard

Subjects

Organic pigments -- Spectra, Organic pigments -- Properties, Organic pigments -- Research, Excited state chemistry -- Research, Absorption -- Research, Chemicals, plastics and rubber industries

Published

2009

45. The photodissociation of HNCO in the S[sub 1] band: A five-dimensional classical trajectory study.

Author

Klossika, Jorg-Joachim and Schinke, Reinhard

Subjects

*PHOTODISSOCIATION, *ISOCYANIC acid

Abstract

Studies the photodissociation of isocyanic acid, HNCO, in the S[sub 1] electronic state. Potential energy surface; Vibrational-rotational state distributions of the diatomic fragments; Effects of the pre-excitation of the HN stretching mode by several quanta.

Published

1999

46. The unimolecular dissociation of HCO. IV. Variational calculation of Siegert states.

Author

Keller, Hans-Martin and Schinke, Reinhard

Subjects

*MESOMERISM, *UNIMOLECULAR reactions, *DISSOCIATION (Chemistry), *SCATTERING (Physics)

Abstract

Presents a variational method for calculating complex resonance states in unimolecular dissociation reactions. Basis of the approach on the log-derivative version of the Kohn variational principle; Formulation of the basic matrix equations in terms of scattering-wave boundary conditions yielding the resonance states as homogenous solutions for singular energies.

Published

1999

47. Photodissociation of HF in ArnHF (n=1–14,54) van der Waals clusters: Effects of the solvent cluster size on the solute fragmentation dynamics.

Author

Schröder, Thomas, Schinke, Reinhard, Liu, Suyan, Bacic, Zlatko, and Moskowitz, Jules W.

Subjects

*PHOTODISSOCIATION, *HYDROGEN fluoride, *QUASIMOLECULES, *ELECTRONIC excitation

Abstract

A comprehensive study of the photodissociation of HF in ArnHF van der Waals clusters, with n=1-14,54, for an ultrashort δ(t)-pulse excitation, is presented. The emphasis is on the dependence of the photodissociation dynamics of the HF solute molecule on the size and geometry of the Arn solvent cluster. This cluster size range encompasses formation and closing of the first solvation shell, which occurs for n=12, the addition of the complete second solvent layer (n=54), as well as the change of the HF location in the cluster, from a surface site for n≤8 to the interior of a cage for n≥9 clusters. Evolution of the fragmentation dynamics is revealed by following how the H-atom kinetic energy and angular distributions, the survival probability, and cluster fragmentation patterns change as a function of the cluster size and structure. Classical trajectories are used to simulate the photodissociation dynamics. The probability distributions of the initial coordinates and momenta of the H and F atom are defined by accurate quantum five-dimensional eigenstates of the coupled, very anharmonic large amplitude intermolecular vibrations of HF in the cluster. All aspects of the dissociation process studied here are found to exhibit a strong dependence on the size and geometry of the ArnHF clusters. © 1995 American Institute of Physics. [ABSTRACT FROM AUTHOR]

Published

1995

48. Emission spectroscopy of dissociating H2S: Influence of nonadiabatic coupling.

Author

Heumann, Bernd and Schinke, Reinhard

Subjects

*EMISSION spectroscopy, *POTENTIAL energy surfaces, *DIPOLE moments

Abstract

The emission spectroscopy of H2S excited in the first absorption band around 195 nm is investigated theoretically using ab initio potential energy surfaces (PES) and transition dipole moment functions. As shown in our previous studies, the photodissociation involves two excited electronic states, one which is binding and another one which is dissociative. The nonadiabatic coupling between these two states is very strong and described in a diabatic representation in which only the binding state is optically excited while the dissociative state is dark. As in the case of H2O excited in the 165 nm band, the emission spectrum shows a long progression of stretching states up to seven HS vibrational quanta. In contrast to water, however, some weak activity in the bending mode is also observed. Most remarkable is a prominent wavelength dependence which is attributed to the strong nonadiabatic coupling between the two excited electronic states. The agreement with experimental data is only fair; the essential features of the measurements are qualitatively reproduced, finer details such as the wavelength dependence are, however, not well described. It is concluded that more accurate ab initio input data are required in order to reproduce all details of the measured emission spectra. [ABSTRACT FROM AUTHOR]

Published

1994

49. Molecular spectroscopy with light pulses of arbitrary pulse shape and field strength: A nonperturbative approach.

Author

Ebel, Gernot and Schinke, Reinhard

Subjects

*MOLECULAR spectroscopy, *FOURIER transforms, *ELECTRIC fields, *ENERGY transfer, *SCHRODINGER equation

Abstract

We present a novel approach to molecular spectroscopy with light pulses of arbitrary strength and duration. The key quantity is the frequency-resolved net energy transfer dE/dω which reveals at which frequencies energy is transferred from the field to the molecule (absorption) or from the molecule to the field (stimulated emission). It is shown that dE/dω can be expressed as the Fourier transform of the cross-correlation function of the molecular polarization P(t) and the time derivative of the applied field, dE/dt. In this sense, it is formally equivalent to the absorption cross section under weak-field conditions which, as commonly known, can be represented as the Fourier transform of the autocorrelation function S(t). The time-dependent polarization P(t) is determined by exact integration of the time-dependent Schrödinger equation including the light-matter interaction to all orders. It is shown that under weak-field conditions the expression for dE/dω reduces to the well-known cross section formula in the time-dependent picture of spectroscopy, multiplied by the spectral intensity of the light pulse. Therefore, we consider the expression for the frequency-resolved energy transfer, which is valid for arbitrary electric fields, as the natural extension of the absorption cross section in the weak-field limit. Furthermore, dE/dω is shown to be formally equivalent to the change of the spectral intensity, ΔI(ω), of an optical pulse after transmission through a sample, the latter being derived by solving Maxwell’s equations under well-known approximations. The theory is applied to a simple one-dimensional model with two electronic states and the frequency-resolved energy transfer is investigated as a function of the field strength. For sufficiently strong fields, dE/dω exhibits transitions between essentially all vibrational levels in the ground and all states in the excited electronic manifold. The new expression... [ABSTRACT FROM AUTHOR]

Published

1994

50. Resonances in the photodissociation of HCl in the Ar–HCl van der Waals complex: How prominent are they?

Author

Schröder, Thomas, Schinke, Reinhard, Mandziuk, Margaret, and Bacˇic, Zlatko

Subjects

*PHOTODISSOCIATION, *QUASIMOLECULES, *MESOMERISM

Abstract

We investigate the cage effect in the ultraviolet (UV) photodissociation of the Ar...HCl van der Waals complex, especially the possibility of resonance structures caused by trapping of the hydrogen atom between its heavy partners as recently highlighted by Garcia-Vela and Gerber [J. Chem. Phys. 98, 427 (1993)]. The dynamics is described by solving the time-dependent Schrödinger equation employing the standard Jacobi coordinates which are routinely used for triatomic systems. Due to the large size of the required grid, exact three-dimensional (3D) wave packet calculations are extremely time consuming and could be followed up to 20 fs only. This time is sufficient for calculating the absorption spectrum, but too short for determining the final kinetic energy distributions of the fragment atoms. Therefore, the photodissociation dynamics is mainly treated in a vibrationally sudden approximation, in which the dynamical calculations are performed for a range of fixed ArCl bond distances, and the results averaged over this bond length. 3D classical trajectory calculations show that the energy transfer out of the dissociative HCl mode is very weak (∼5% of the total energy), supporting the application of the sudden approximation. In this approximation, both the absorption spectrum and the kinetic energy distribution associated with the dissociating HCl motion exhibit very weak diffuse structures (resonances) which, following the work of Garcia-Vela and Gerber, can be assigned to the transient vibrational motion of hydrogen between Ar and Cl. However, in our calculations these structures are much less pronounced than in the work of Garcia-Vela and Gerber. The very small amplitudes of the resonance features indicate that trapping in the dissociation of HCl in Ar...HCl is marginal, and much less important than suggested by the previous studies of Garcia-Vela et al. Furthermore, in contrast to the work reported by Garcia-Vela et al., we do not find any evidence... [ABSTRACT FROM AUTHOR]

Published

1994