Several Levels of Theory for Description of Isotope Effects in Ozone: Symmetry Effect and Mass Effect.

The essential components of theory for the description of isotope effects in recombination reaction that forms ozone are presented, including the introduction of three reaction pathways for symmetric and asymmetric isotopomers, a brief review of relevant experimental data for singly- and doubly substituted isotopologues, the definitions of ζ-effect and η-effect, and the introduction of isotopic enrichment δ. Two levels of theory are developed to elucidate the role of molecular symmetry, atomic masses, vibrational zero-point energies, and rotational excitations in the recombination process. The issue of symmetry is not trivial, since the important factors, such as 1/2 and 2, appear in seven different places in the formalism. It is demonstrated that if all these effects are taken into account properly, then no anomalous isotope effects emerge. At the next level of theory, a model is considered in which one scattering resonance (sitting right at the top of centrifugal barrier) is introduced per ro-vibrational channel. It is found that this approach is equivalent to statistical treatment with partition functions at the transition state. Accurate calculations using hyper-spherical coordinates show that no isotope effects come from difference in the number of states. In contrast, differences in vibrational and rotational energies lead to significant isotope effects. However, those effects appear to be local, found for the rather extreme values of rotational quantum numbers. They largely cancel when rate coefficients are computed for the thermal distribution of rotational excitations. Although large isotope effects (observed in experiments) are not reproduced here, this level of theory can be used as a foundation for more detailed computational treatment, with accurate information about resonance energies and lifetimes computed and included.

[1]  A. Teplukhin,et al.  Several levels of theory for description of isotope effects in ozone: Effect of resonance lifetimes and channel couplings. , 2018, The Journal of chemical physics.

[2]  A. Teplukhin,et al.  One possible source of mass-independent fractionation of sulfur isotopes in the Archean atmosphere of Earth , 2017 .

[3]  A. Teplukhin Theoretical Study of Ozone Forming Recombination Reaction and Anomalous Isotope Effect Associated With It , 2017 .

[4]  A. Teplukhin,et al.  Efficient method for calculations of ro-vibrational states in triatomic molecules near dissociation threshold: Application to ozone , 2016 .

[5]  V. Tyuterev,et al.  Lifetimes and wave functions of ozone metastable vibrational states near the dissociation limit in a full-symmetry approach , 2016, 1607.04749.

[6]  A. Teplukhin,et al.  A full-dimensional model of ozone forming reaction: the absolute value of the recombination rate coefficient, its pressure and temperature dependencies. , 2016, Physical chemistry chemical physics : PCCP.

[7]  D. Babikov,et al.  On stabilization of scattering resonances in recombination reaction that forms ozone. , 2016, The Journal of chemical physics.

[8]  T. Carrington,et al.  Calculated vibrational states of ozone up to dissociation. , 2016, The Journal of chemical physics.

[9]  S. Mahapatra,et al.  Differential Cross Sections and Product Rovibrational Distributions for (16)O + (32)O2 and (18)O + (36)O2 Collisions. , 2015, The journal of physical chemistry. A.

[10]  Zhigang Sun,et al.  Kinetic isotope effect of the (16)O + (36)O2 and (18)O + (32)O2 isotope exchange reactions: Dominant role of reactive resonances revealed by an accurate time-dependent quantum wavepacket study. , 2015, The Journal of chemical physics.

[11]  Zhigang Sun,et al.  State-to-state reaction dynamics of (18)O+(32)O2 studied by a time-dependent quantum wavepacket method. , 2015, The Journal of chemical physics.

[12]  A. Teplukhin,et al.  Visualization of Potential Energy Function Using an Isoenergy Approach and 3D Prototyping , 2015 .

[13]  A. Teplukhin,et al.  Interactive tool for visualization of adiabatic adjustment in APH coordinates for computational studies of vibrational motion and chemical reactions , 2014 .

[14]  Hua Guo,et al.  Communication: An accurate global potential energy surface for the ground electronic state of ozone. , 2013, The Journal of chemical physics.

[15]  D. Babikov,et al.  Global permutationally invariant potential energy surface for ozone forming reaction. , 2013, The Journal of chemical physics.

[16]  D. Babikov,et al.  On molecular origin of mass-independent fractionation of oxygen isotopes in the ozone forming recombination reaction , 2013, Proceedings of the National Academy of Sciences.

[17]  D. Babikov,et al.  Efficient quantum-classical method for computing thermal rate constant of recombination: application to ozone formation. , 2012, The Journal of chemical physics.

[18]  G. Domínguez,et al.  The physical chemistry of mass-independent isotope effects and their observation in nature. , 2012, Annual review of physical chemistry.

[19]  Hua Guo,et al.  Communication: highly accurate ozone formation potential and implications for kinetics. , 2011, The Journal of chemical physics.

[20]  D. Babikov,et al.  Collisional stabilization of van der Waals states of ozone. , 2011, The Journal of chemical physics.

[21]  D. Babikov,et al.  Mixed quantum-classical theory for the collisional energy transfer and the rovibrational energy flow: application to ozone stabilization. , 2011, The Journal of chemical physics.

[22]  R. Marcus,et al.  Coriolis coupling as a source of non-RRKM effects in ozone molecule: Lifetime statistics of vibrationally excited ozone molecules. , 2010, The Journal of chemical physics.

[23]  R. Schinke,et al.  Vibrational energy transfer in Ar–O3 collisions: comparison of rotational sudden, breathing sphere, and classical calculations , 2010 .

[24]  R. Schinke,et al.  Towards quantum mechanical description of the unconventional mass-dependent isotope effect in ozone: resonance recombination in the strong collision approximation. , 2009, The Journal of chemical physics.

[25]  D. Babikov,et al.  Semiclassical wave packet treatment of scattering resonances: application to the delta zero-point energy effect in recombination reactions. , 2007, Physical review letters.

[26]  M. Thiemens HISTORY AND APPLICATIONS OF MASS-INDEPENDENT ISOTOPE EFFECTS , 2006 .

[27]  P. Fleurat‐Lessard,et al.  Dynamical studies of the ozone isotope effect: A status report. , 2006, Annual review of physical chemistry.

[28]  J. Bowman,et al.  Quantum inelastic scattering study of isotope effects in ozone stabilization dynamics , 2005 .

[29]  J. Troe,et al.  The role of the radical-complex mechanism in the ozone recombination/dissociation reaction. , 2005, Physical chemistry chemical physics : PCCP.

[30]  R. Schinke,et al.  Temperature dependent energy transfer in Ar-O3 collisions. , 2005, The Journal of chemical physics.

[31]  B. Tuzson Symmetry Specific Study of Ozone Isotopomer Formation , 2005 .

[32]  D. Krankowsky,et al.  Assessment of the ozone isotope effect , 2005 .

[33]  M. Thiemens Non‐Mass‐Dependent Isotopic Fractionation Processes: Mechanisms and Recent Observations in Terrestrial and Extraterrestrial Environments , 2004 .

[34]  R. Schinke,et al.  Intra- and intermolecular energy transfer in highly excited ozone complexes. , 2004, The Journal of chemical physics.

[35]  D. Clary,et al.  Quantum-mechanical calculations on pressure and temperature dependence of three-body recombination reactions: application to ozone formation rates. , 2004, The Journal of chemical physics.

[36]  M. Thiemens 4.06 – Nonmass-Dependent Isotopic Fractionation Processes: Mechanisms and Recent Observations in Terrestrial and Extraterrestrial Environments , 2003 .

[37]  Robert B. Walker,et al.  Formation of ozone: Metastable states and anomalous isotope effect , 2003 .

[38]  R. T. Pack,et al.  Quantum origin of an anomalous isotope effect in ozone formation , 2003 .

[39]  Robert B. Walker,et al.  Metastable states of ozone calculated on an accurate potential energy surface , 2003 .

[40]  D. Clary,et al.  Quantum-mechanical calculations on termolecular association reactions XY+Z+M→XYZ+M: Application to ozone formation , 2002 .

[41]  Y. Gao,et al.  A theoretical study of ozone isotopic effects using a modified ab initio potential energy surface , 2002 .

[42]  Y. Gao,et al.  On the theory of the strange and unconventional isotopic effects in ozone formation , 2002 .

[43]  D. Krankowsky,et al.  Kinetic origin of the ozone isotope effect: a critical analysis of enrichments and rate coefficients , 2001 .

[44]  Y. Gao,et al.  Strange and Unconventional Isotope Effects in Ozone Formation , 2001, Science.

[45]  Yide Gao,et al.  On the theory of the strange and unconventional isotopic effects in ozone formation , 2001 .

[46]  R. Marcus,et al.  An intramolecular theory of the mass-independent isotope effect for ozone. II. Numerical implementation at low pressures using a loose transition state , 2000 .

[47]  D. Krankowsky,et al.  Third-body dependence of rate coefficients for ozone formation in 16O–18O mixtures , 2000 .

[48]  D. Krankowsky,et al.  RELATIVE FORMATION RATES OF 50O3 AND 52O3 IN 16O-18O MIXTURES , 1999 .

[49]  R. Marcus,et al.  An intramolecular theory of the mass-independent isotope effect for ozone. I , 1999 .

[50]  Erbacher,et al.  Ozone isotope enrichment: isotopomer-specific rate coefficients , 1999, Science.

[51]  M. Thiemens,et al.  Mass-independent isotope effects in planetary atmospheres and the early solar system. , 1999, Science.

[52]  K. Mauersberger,et al.  Surprising rate coefficients for four isotopic variants of O+O2+M , 1997 .

[53]  D. Krankowsky,et al.  Heavy Ozone--A Difficult Puzzle to Solve , 1996, Science.

[54]  G. A. Parker,et al.  Quantum reactive scattering in three dimensions using hyperspherical (APH) coordinates. Theory , 1987 .

[55]  G. A. Parker,et al.  Quantum reactive scattering in three dimensions using hyperspherical (APH) coordinates. tests on H+H2 and D+H2 , 1987 .

[56]  P. Bunker,et al.  Molecular symmetry and spectroscopy , 1979 .