Your search keyword '"Mikhail B. Sevryuk"' showing total 66 results

1. Statistical dynamics of bimolecular recombination of alkali and halide ions

Author

Vyacheslav M. Akimov, Vladimir M. Azriel, Ekaterina V. Ermolova, Dmitrii B. Kabanov, Lev Yu. Rusin, and Mikhail B. Sevryuk

Subjects

General Earth and Planetary Sciences, General Agricultural and Biological Sciences, General Environmental Science

Published

2022

2. Detailed dynamics of direct three-body recombination of singly charged ions

Author

Vyacheslav M. Akimov, Vladimir M. Azriel', Ekaterina V. Ermolova, Dmitrii B. Kabanov, Lyubov' I. Kolesnikova, Lev Yu. Rusin, and Mikhail B. Sevryuk

Subjects

inorganic chemicals, integumentary system, General Physics and Astronomy, Physical and Theoretical Chemistry, circulatory and respiratory physiology

Abstract

We analyze randomly selected trajectories for cesium ions recombining with fluoride (iodide) ions in the presence of argon (xenon) atoms.

Published

2022

3. Partial Preservation of Frequencies and Floquet Exponents of Invariant Tori in the Reversible KAM Context 2

Author

Mikhail B. Sevryuk

Subjects

Statistics and Probability, Floquet theory, Pure mathematics, Mathematics::Dynamical Systems, General Mathematics, Context (language use), Dynamical Systems (math.DS), Fixed point, 01 natural sciences, 010305 fluids & plasmas, 0103 physical sciences, FOS: Mathematics, Mathematics - Dynamical Systems, 0101 mathematics, Invariant (mathematics), Mathematics::Symplectic Geometry, Mathematics, 70K43, 70H33, Kolmogorov–Arnold–Moser theorem, Applied Mathematics, 010102 general mathematics, Torus, General Medicine, Codimension, Mathematics::Spectral Theory, Manifold

Abstract

We consider the persistence of smooth families of invariant tori in the reversible context 2 of KAM theory under various weak nondegeneracy conditions via Herman's method. The reversible KAM context 2 refers to the situation where the dimension of the fixed point manifold of the reversing involution is less than half the codimension of the invariant torus in question. The nondegeneracy conditions we employ ensure the preservation of any prescribed subsets of the frequencies of the unperturbed tori and of their Floquet exponents (the eigenvalues of the coefficient matrix of the variational equation along the torus)., 34 pages. The material of Section 4 (included to achieve a self-contained presentation) almost coincides with that of Section 4 in arXiv:1612.07653

Published

2021

4. Dynamics of third order direct three-body recombination of heavy ions

Author

L. I. Kolesnikova, D. B. Kabanov, Lev Yu. Rusin, V. M. Akimov, E. V. Ermolova, Mikhail B. Sevryuk, and V. M. Azriel

Subjects

Physics, Range (particle radiation), 010304 chemical physics, Diabatic, General Physics and Astronomy, chemistry.chemical_element, 010402 general chemistry, 01 natural sciences, Acceptor, Potential energy, 0104 chemical sciences, Rotational energy, Ion, Xenon, chemistry, 0103 physical sciences, Physical and Theoretical Chemistry, Atomic physics, Excitation

Abstract

The direct three-body recombination reactions Cs+ + X− + R → CsX + R (X = F, I and R = Ar, Xe) are studied within the quasiclassical trajectory method using diabatic semiempirical potential energy surfaces, the encounters of the ions being non-central. The collision energies range between 1 and 10 eV (values typical for low temperature plasma), while the so-called delay parameter, which characterizes the delay in the arrival of the neutral atom R in relation to the time instant when the distance between the ions attains its minimum, is equal to 0 or 20%. The calculation results include the recombination excitation functions, the opacity functions, and the vibrational and rotational energy distributions of the recombination products. All the four reactions considered exhibit similar overall statistical dynamics, but each process has its own features. On the whole, for both the recombining pairs Cs+ + F− and Cs+ + I−, xenon is more effective than argon as an acceptor of excess energy from the ion pair. The rotational energy distributions of the salt molecules CsF and CsI are almost equilibrium, whereas the vibrational energy distributions are strongly non-equilibrium.

Published

2021

5. A Source of a Seeded Supersonic Beam of Alkali Halide Molecules

Author

Mikhail B. Sevryuk, L. Yu. Rusin, L. I. Kolesnikova, V. M. Azriel, D. B. Kabanov, V. M. Akimov, and E. V. Ermolova

Subjects

010302 applied physics, Stagnation temperature, Materials science, Hydrogen, 010308 nuclear & particles physics, Analytical chemistry, chemistry.chemical_element, Halide, Alkali metal, 01 natural sciences, chemistry, Torr, 0103 physical sciences, Stagnation pressure, Instrumentation, Helium, Beam (structure)

Abstract

The design of a source of a seeded supersonic beam of alkali halide molecules or other vaporized solids is described. At a carrier gas (hydrogen or helium) stagnation pressure of 0.5–5 atm, a stagnation temperature of 1000 K, and a partial seed species pressure of 10–2 Torr, the intensity of the salt beam was 1014 sr–1 s–1 and the energy of molecules in the beam varied from 5.5 to 7.5 eV for a mixture with helium and from 7.5 to 15.5 eV for a mixture with hydrogen. The modular design of the source provides the easy replacement of its functional units.

Published

2020

6. Scattering of particles from a solid surface: the impulsive model of composite encounters

Author

V. M. Azriel, Mikhail B. Sevryuk, L. I. Kolesnikova, V. M. Akimov, and Lev Yu. Rusin

Subjects

Chemical Physics (physics.chem-ph), Physics, 0303 health sciences, Scattering, Solid surface, Composite number, FOS: Physical sciences, 01 natural sciences, Ion, 03 medical and health sciences, Classical mechanics, 030301 anatomy & morphology, Physics - Chemical Physics, Reciprocity (electromagnetism), 0103 physical sciences, Atom, General Earth and Planetary Sciences, General Agricultural and Biological Sciences, 010303 astronomy & astrophysics, Positive probability, General Environmental Science

Abstract

We propose a general impulsive model for scattering of molecules from a flat solid surface. It is assumed within the framework of this model that an encounter of an atom (or ion) with the surface is a series of elastic (in the direction normal to the surface) hits of the atom against surface pseudoparticles, the hits instantly following each other. To each atom, one assigns two infinite sequences of masses of pseudoparticles. The model is a far-reaching generalization of the well-known hard cube model. Criteria for both finiteness and infinity of series of hits are formulated, based on the masses of pseudoparticles and the mass of the atom. It is shown that in virtually all the cases, any number of hits in a series occurs with a positive probability. The proposed model does not satisfy the reciprocity condition., 18 pages and 1 figure, submitted to Rendiconti Lincei. Scienze Fisiche e Naturali

Published

2019

7. General impulsive models of scattering of molecules from a solid surface without tangential forces

Author

Lev Yu. Rusin, V. M. Akimov, Mikhail B. Sevryuk, V. M. Azriel, and L. I. Kolesnikova

Subjects

Materials science, Scattering, Solid surface, Molecule, Molecular physics

Published

2019

8. Hamiltonian and reversible systems with smooth families of invariant tori

Author

Mikhail B. Sevryuk

Subjects

Pure mathematics, General Mathematics, Isotropy, Torus, Dynamical Systems (math.DS), Frequency vector, Hamiltonian system, symbols.namesake, Phase space, symbols, FOS: Mathematics, 70K43 70H12 70H33 70H08, Mathematics - Dynamical Systems, Hamiltonian (quantum mechanics), Mathematics::Symplectic Geometry, Lagrangian, Mathematics, Symplectic geometry

Abstract

For various values of n, d, and the phase space dimension, we construct simple examples of Hamiltonian and reversible systems possessing smooth d-parameter families of invariant n-tori carrying conditionally periodic motions. In the Hamiltonian case, these tori can be isotropic, coisotropic, or atropic (neither isotropic nor coisotropic). The cases of non-compact and compact phase spaces are considered. In particular, for any N no less than 3 and any vector omega in R^N, we present an example of an analytic Hamiltonian system with N degrees of freedom and with an isolated (and even unique) invariant N-torus carrying conditionally periodic motions with frequency vector omega (but this torus is atropic rather than Lagrangian and the symplectic form is not exact). Examples of isolated atropic invariant tori carrying conditionally periodic motions are given in the paper for the first time. The paper can also be used as an introduction to the problem of the isolatedness of invariant tori in Hamiltonian and reversible systems., 23 pages, the paper is intended for Indagationes Mathematicae

Published

2020

9. Two Mechanisms of Recombination of Atomic Ions

Author

L. Yu. Rusin, V. M. Azriel, Mikhail B. Sevryuk, D. B. Kabanov, V. M. Akimov, E. V. Ermolova, and L. I. Kolesnikova

Subjects

Excitation function, Physics, Energetic neutral atom, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Diatomic molecule, Molecular physics, 0104 chemical sciences, Ion, Rotational energy, Elementary reaction, 0202 electrical engineering, electronic engineering, information engineering, Cluster (physics), 020201 artificial intelligence & image processing, Physical and Theoretical Chemistry, Recombination

Abstract

We compare the dynamics of two elementary reactions of recombination of atomic ions, namely, of the termolecular process of two ions and the third body (1) and of the bimolecular interaction of an ion with the diatomic cluster (2) consisting of the second ion and the neutral atom. It is shown that, despite the fact that both processes yield the same products, the main dynamical characteristics of these processes differ. First of all this concerns the excitation function which confines recombination for (2) by a collision energy up to 2 eV. The opacity functions of both processes have different structures. The distributions of the product vibrational energy in both the processes exhibit a non-equilibrium character, while the rotational energy distributions are equilibrium.

Published

2018

10. Dissociation of Potassium Iodide at a Graphite Surface within the Framework of an Impulsive Model

Author

V. M. Akimov, E. V. Ermolova, V. M. Azriel, L. I. Kolesnikova, L. Yu. Rusin, and Mikhail B. Sevryuk

Subjects

Materials science, Ionic bonding, Halide, 010402 general chemistry, Alkali metal, 01 natural sciences, Molecular physics, Diatomic molecule, Dissociation (chemistry), 0104 chemical sciences, Ion, 0103 physical sciences, Molecule, Graphite, Physical and Theoretical Chemistry, 010303 astronomy & astrophysics

Abstract

An impulsive model of dissociation of diatomic molecules with an ionic bond (for instance, alkali halide molecules) at a graphite surface is proposed. Within the framework of this model, a single encounter of an ion with the surface can consist of several elastic hits of the ion against graphite pseudoparticles of various masses. These hits instantly follow each other and are described in general in the same way as in Logan’s and Stickney’s well-known “hard-cube model” of scattering of atoms from a solid surface. The calculation results for dissociation of KI molecules with a translational energy from 4 to 14 eV are presented.

Published

2018

11. Hyperspherical coordinates and energy partitions for reactive processes and clusters

Author

Federico Palazzetti, Andrea Lombardi, and Mikhail B. Sevryuk

Subjects

Physics, Discretization, Hyperspherical harmonics, Nuclear Theory, Coordinate system, Semiclassical physics, Eigenfunction, Hyperspherical coordinates, Energy partitions, Classical mechanics, Harmonics, Spin network, Representation (mathematics), Quantum

Abstract

The hyperspherical coordinate systems have been developed for the study of few-body scattering problems of nuclear and molecular physics, for example in the practical implementation of demanding quantum calculations typical of chemical reactions. The hyperangular momenta and their eigenfunctions, the hyperspherical harmonics, are the mathematical apparatus characterizing the hyperspherical representation of molecular dynamics. To circumvent the restriction to the application of the hyperspherical methods, due to exceedingly high computational costs, a classical mechanics hyperspherical formulation has been developed suitable for applications to clusters and large molecular system dynamics. The asymptotic theory of generalized harmonics connected with that of spin networks establishes semiclassical connections for treating discretization procedures, specifically, the hyperquantization algorithm treated by us elsewhere.The hyperspherical coordinate systems have been developed for the study of few-body scattering problems of nuclear and molecular physics, for example in the practical implementation of demanding quantum calculations typical of chemical reactions. The hyperangular momenta and their eigenfunctions, the hyperspherical harmonics, are the mathematical apparatus characterizing the hyperspherical representation of molecular dynamics. To circumvent the restriction to the application of the hyperspherical methods, due to exceedingly high computational costs, a classical mechanics hyperspherical formulation has been developed suitable for applications to clusters and large molecular system dynamics. The asymptotic theory of generalized harmonics connected with that of spin networks establishes semiclassical connections for treating discretization procedures, specifically, the hyperquantization algorithm treated by us elsewhere.

Published

2019

12. Integrable Hamiltonian systems with a periodic orbit or invariant torus unique in the whole phase space

Author

Mikhail B. Sevryuk

Subjects

Physics, Integrable system, General Mathematics, 37J45 70H12 70K42 70K43 70H33, 010102 general mathematics, Degrees of freedom (physics and chemistry), Torus, Dynamical Systems (math.DS), 01 natural sciences, Hamiltonian system, Simple (abstract algebra), Phase space, 0103 physical sciences, FOS: Mathematics, 010307 mathematical physics, Uniqueness, 0101 mathematics, Invariant (mathematics), Mathematics - Dynamical Systems, Mathematical physics

Abstract

It is very well known that periodic orbits of autonomous Hamiltonian systems are generically organized into smooth one-parameter families (the parameter being just the energy value). We present a simple example of an integrable Hamiltonian system (with an arbitrary number of degrees of freedom greater than one) with a unique periodic orbit in the phase space (which is not compact). Similar examples are given for Hamiltonian systems with a unique invariant torus (of any prescribed dimension) carrying conditionally periodic motions. Parallel examples for Hamiltonian systems with a compact phase space and with uniqueness replaced by isolatedness are also constructed. Finally, reversible analogues of all the examples are described., 8 pages, submitted to the Arnold Mathematical Journal

Published

2018

13. Herman's Approach to Quasi-Periodic Perturbations in the Reversible KAM Context 2

Author

Mikhail B. Sevryuk

Subjects

Pure mathematics, Mathematics::Dynamical Systems, 70K43, 70H33, Kolmogorov–Arnold–Moser theorem, General Mathematics, 010102 general mathematics, Context (language use), Torus, Dynamical Systems (math.DS), Codimension, Fixed point, 01 natural sciences, Manifold, 010101 applied mathematics, FOS: Mathematics, Involution (philosophy), Mathematics - Dynamical Systems, 0101 mathematics, Invariant (mathematics), Mathematics

Abstract

We revisit non-autonomous systems depending quasi-periodically in time within the reversible context 2 of KAM theory and obtain Whitney smooth families of invariant tori in such systems via Herman's method. The reversible KAM context 2 refers to the situation where the dimension of the fixed point manifold of the reversing involution is less than half the codimension of the invariant torus in question., Comment: 22 pages

Published

2016

14. Statistical characteristics of the motion of a pair of heavy ions in non-convex cavities of complicated geometry with fixed crosspieces and charges

Author

L. Yu. Rusin, L. I. Kolesnikova, and Mikhail B. Sevryuk

Subjects

Series (mathematics), Chemistry, Nuclear Theory, Inelastic collision, Boundary (topology), Motion (geometry), Absolute value, Geometry, Ion, medicine.anatomical_structure, medicine, Molecule, Physical and Theoretical Chemistry, Atomic physics, Nuclear Experiment, Nucleus

Abstract

Using the method of classical trajectories, the motion of a pair of ions Cs+ and Cl– in three non-convex closed cavities of complicated geometry containing neutral cylindrical “crosspieces” and charged spherical “nuclei” is simulated. The collisions of the ions with the cavity boundary, crosspieces, and nuclei are supposed to be inelastic. The signs of the charges of the nuclei are varied. In each cavity, in one of the calculation series, the nuclei are assumed to be shielded (to carry charges smaller than 1 a.u. in absolute value), whereas in another calculation series, the possibility of the mutual neutralization of an ion and an oppositely charged nucleus at their encounter is taken into account. The statistics of various events, such as the “stickings” of ions to nuclei, neutralizations of ions and nuclei, collisions of ions with obstacles, recombinations of ions, and dissociations of the CsCl ionic-bond molecule are analyzed.

Published

2015

15. IMPULSIVE MODEL FOR DISSOCIATION OF DIATOMIC MOLECULES WITH AN IONIC BOND AT A GRAPHITE SURFACE

Author

V. M. Akimov, Mikhail B. Sevryuk, V. M. Azriel, L. I. Kolesnikova, and Lev Yur’evich Rusin

Subjects

Chemistry, Physical chemistry, Ionic bonding, General Medicine, Graphite, Diatomic molecule, Dissociation (chemistry)

Published

2018

16. Families of invariant tori in KAM theory: interplay of integer characteristics

Author

Mikhail B. Sevryuk

Subjects

Pure mathematics, Kolmogorov–Arnold–Moser theorem, 010102 general mathematics, Principal (computer security), Torus, Context (language use), Dynamical Systems (math.DS), 01 natural sciences, 010101 applied mathematics, Mathematics (miscellaneous), 37J40, 70H08, 70H33, 70K43, Integer, Simple (abstract algebra), FOS: Mathematics, 0101 mathematics, Invariant (mathematics), Mathematics - Dynamical Systems, Mathematics

Abstract

The purpose of this brief note is twofold. First, we summarize in a very concise form the principal information on Whitney smooth families of quasi-periodic invariant tori in various contexts of KAM theory. Our second goal is to attract (via an informal discussion and a simple example) the experts' attention to the peculiarities of the so-called excitation of elliptic normal modes in the reversible context 2., 19 pages

Published

2017

17. A hard sphere model for direct three-body recombination of heavy ions

Author

L. Yu. Rusin, Mikhail B. Sevryuk, and E. V. Ermolova

Subjects

Range (particle radiation), Third body, Energetic neutral atom, Opacity, Chemistry, Ionic bonding, Hard spheres, Physical and Theoretical Chemistry, Atomic physics, Recombination, Ion

Abstract

We describe a hard sphere model of direct three-body recombination of the Cs+ and Br− ions in the presence of neutral atoms Hg, Xe, Kr, or Ar as the third bodies. Calculations are carried out for the ion approach energy and the third body energy in the range from 1 to 10 eV under the assumption of non-central approach of the ions. The calculation results include the dependences of the total recombination probability on these energies as well as the opacity functions for two impact parameters and the dependences of the recombination probability on the angles determining the mutual orientation of the velocities of the reagents. The classification of the three-body collisions according to the sequences of pairwise encounters of the particles is considered. The most widespread mechanism of energy removal from the ionic pair is a single impact of the third body with the Br− ion.

Published

2014

18. Translation of the V. I. Arnold paper 'From Superpositions to KAM Theory' (Vladimir Igorevich Arnold. Selected — 60, Moscow: PHASIS, 1997, pp. 727–740)

Author

Mikhail B. Sevryuk

Subjects

Algebra, Mathematics (miscellaneous), Dynamical systems theory, Kolmogorov–Arnold–Moser theorem, Calculus, Translation (geometry), Exposition (narrative), Mathematics

Abstract

V. I. Arnold (12 June 1937–3 June 2010) published several papers where he described, in the form of recollections, his two earliest research problems (superpositions of continuous functions and quasi-periodic motions in dynamical systems), the main results and their interrelations: [A1], then [A2] (reprinted as [A4, A6]), and [A3] (translated into English by the author as [A5]). The first exposition [A1] has never been translated into English; however, it contains many details absent in the subsequent articles. It seems therefore that publishing the English translation of the paper [A1] would not be superfluous. What follows is this translation. In many cases, the translator gives complete bibliographic descriptions of various papers mentioned briefly in the original Russian text. The English translations of papers in Russian are also pointed out where possible. A related material is contained also in Arnold’s recollections “On A.N. Kolmogorov”. Slightly different versions of these reminiscences were published several times in Russian and English [A7–A12]. The early history of KAM theory is also discussed in detail in the recent brilliant semi-popular book [A13].

Published

2014

19. Dynamics of a heavy ionic pair in a cavity with an elastic or inelastic boundary, crosspieces, and fixed charges of opposite sign

Author

L. I. Kolesnikova, L. Yu. Rusin, and Mikhail B. Sevryuk

Subjects

Physics, Nuclear Theory, Electromagnetic shielding, Ionic bonding, Molecule, Physical and Theoretical Chemistry, Atomic physics, Nuclear Experiment, Dissociation (chemistry), Ion

Abstract

Using the method of classical trajectories, we have simulated the motion of a pair of ions Cs+ and Cl− in ellipsoidal cavities containing neutral cylindrical “crosspieces” and charged spherical “nuclei” (both the signs and the absolute values of the charges of the nuclei were varied). Both elastic and inelastic encounters of the ions with the cavity boundary, crosspieces, and nuclei are considered. Most attention is paid to the statistics of the “captures” of trajectories by the nuclei (for elastic encounters of the ions with the obstacles) and to that of the “stickings” of the ions to the nuclei (for inelastic encounters), as well as to the statistics of the ion recombination events and the dissociation events of the corresponding molecule with an ionic bond. The dynamical consequences of nuclei shielding (i.e., a decrease in the absolute values of the nuclei charges) have been determined.

Published

2013

20. Dynamics of two-stage direct three-body recombination of ions

Author

Lev Yu. Rusin, V. M. Azriel, and Mikhail B. Sevryuk

Subjects

Third body, Chemical physics, Chemistry, Atom, Dynamics (mechanics), Complex formation, General Physics and Astronomy, Molecule, Physical and Theoretical Chemistry, Atomic physics, Two stages, Recombination, Ion

Abstract

Single-stage three-body recombination of ions and recombination via intermediate complex formation can be considered as two limiting cases of a general mechanism involving two stages separated by some time interval T , namely, energy removal by the third body and closest approach of the ions. Any of these can occur first. Particular dynamics of nascent molecule stabilization is determined by various kinematic parameters including two collision energies and the lag T . In this paper, recombination dynamics of the Cs + and Br − ions in the presence of the Xe atom is studied by quasiclassical trajectories. If T vanishes (one-stage process), stabilization proceeds chiefly via energy transfer in encounters of Xe with both ions approaching each other. If the energy removal stage is late, dynamics changes drastically, stabilization occurring via interaction of Xe mainly with only one ion. This three-body recombination mechanism may be of considerable importance at low pressures in gas medium.

Published

2013

21. Whitney Smooth Families of Invariant Tori within the Reversible Context 2 of KAM Theory

Author

Mikhail B. Sevryuk

Subjects

Pure mathematics, General theorem, 70K43, 70H33, Kolmogorov–Arnold–Moser theorem, 010102 general mathematics, Torus, Dynamical Systems (math.DS), Fixed point, 01 natural sciences, 010101 applied mathematics, Mathematics (miscellaneous), Corollary, FOS: Mathematics, 0101 mathematics, Invariant (mathematics), Mathematics - Dynamical Systems, Mathematics

Abstract

We prove a general theorem on the persistence of Whitney infinitely smooth families of invariant tori in the reversible context 2 of KAM theory. This context refers to the situation where dim Fix G < (codim T)/2 where Fix G is the fixed point manifold of the reversing involution G and T is the invariant torus in question. Our result is obtained as a corollary of the theorem by H.W.Broer, M.-C.Ciocci, H.Hanssmann, and A.Vanderbauwhede of 2009 concerning quasi-periodic stability of invariant tori with singular "normal" matrices in reversible systems., 32 pages

Published

2016

22. The reversible context 2 in KAM theory: the first steps

Author

Mikhail B. Sevryuk

Subjects

Discrete mathematics, Pure mathematics, Mathematics (miscellaneous), Kolmogorov–Arnold–Moser theorem, Torus, Fixed point, Invariant (mathematics), Mathematics

Abstract

The reversible context 2 in KAM theory refers to the situation where dim FixG < 1/2 codim T, here FixG is the fixed point manifold of the reversing involution G and T is the invariant torus one deals with. Up to now, this context has been entirely unexplored. We obtain a first result on the persistence of invariant tori in the reversible context 2 (for the particular case where dim Fix G = 0) using J. Moser’s modifying terms theorem of 1967.

Published

2010

23. Evolution of a pair of classical ions in a cavity with elastic walls, crosspieces, and implanted charges

Author

Mikhail B. Sevryuk, L. Yu. Rusin, and L. I. Kolesnikova

Subjects

Physics, Nuclear Theory, Ionic bonding, Molecule, Physical and Theoretical Chemistry, Atomic physics, Nuclear Experiment, Cavity wall, Dissociation (chemistry), Recombination, Ion

Abstract

Using the method of classical trajectories, we have simulated the motion of a pair of oppositely charged ions in spherical and ellipsoidal cavities, including cavities that contain cylindrical “crosspieces” and positively charged “nuclei.” We supposed that each of the ions reflected off the cavity wall, crosspieces, and nuclei according to the elastic impact law. Most of attention is focused on the statistics of the events of ion recombination and those of dissociation of the corresponding molecule with an ionic bond. When nuclei are absent, recombination and dissociation events are possible only on collisions of the ions with the cavity wall or crosspieces. In the presence of nuclei, on the other hand, the major part of the events occur in time intervals between the collisions of the ions with the cavity wall, crosspieces, or nuclei.

Published

2010

24. The optimization of potential energy surface parameters for the CsCl + RbI system with the use of linear regression analysis

Author

V. M. Akimov, L. Yu. Rusin, V. M. Azriel, and Mikhail B. Sevryuk

Subjects

Cross section (physics), Chemistry, Linear regression, Potential energy surface, Ionic bonding, Physical and Theoretical Chemistry, Atomic physics, Diatomic molecule, Linear function, Excitation, Ion

Abstract

The influence of interaction potential parameters of likely charged ions on cross sections of various channels of a reaction of a pair of diatomic molecules with ionic bonds was studied in terms of quasi-classical trajectory simulation with the use of linear mean-square regressions. In the regression approach, the dependence of the cross section of a given reaction channel on potential parameters at each fixed collision energy is approximated by a linear function. We determined the region of softness parameters of the Cs+-Rb+ and Cl−-I− interaction potentials. This region was optimum for the reproduction of experimental excitation functions of atomic and complex positive ions for the CsCl + RbI → products reaction.

Published

2010

25. On the maximum in the differential cross sections of the F + H2 reaction in the region of small scattering angles

Author

V. M. Akimov, L. I. Kolesnikova, J. P. Toennies, L. Yu. Rusin, V. M. Azriel, and Mikhail B. Sevryuk

Subjects

Total angular momentum quantum number, Scattering, Chemistry, Forward scatter, Potential energy surface, Physics::Chemical Physics, Physical and Theoretical Chemistry, Atomic physics, Ground state, Quantum number, Interference (wave propagation), Quantum

Abstract

By means of quantum mechanical simulation of the reaction F + H2(v = 0; j = 0, 1, 2) → H + HF(v′, j′) on the Stark-Werner ground state potential energy surface at collision energies of 1.84, 2.74, and 3.42 kcal/mol, we have analyzed interference of the “partial waves” corresponding to different values of the total angular momentum J. As the vibrational quantum number v′ of the HF(v′, j′) product increases, the interference for the HF forward scattering becomes noticeably more constructive. This is probably the reason for the maximum in the angular distributions of the HF(v′= 3) molecules at small scattering angles that was discovered experimentally by D.M. Neumark, A.M. Wodtke, G.N. Robinson, C.C. Hayden, and Y.T. Lee, J. Chem. Phys. 82 (7), 3045 (1985) at the same collision energies. We have also determined the intervals of J values most effective for forward scattering of the HF(v′, j′) molecules.

Published

2009

26. Statistics of partitions of the kinetic energy of small nanoclusters

Author

Vincenzo Aquilanti, Andrea Lombardi, and Mikhail B. Sevryuk

Subjects

Physics, Work (thermodynamics), Angular momentum, Particle number, Statistics, Cluster (physics), Particle, Statistical physics, Physical and Theoretical Chemistry, Kinetic energy, Nanoclusters, Rotational energy

Abstract

In Aquilanti, Lombardi, and Sevryuk, J. Chem. Phys. 2004, V. 121, No. 12, P. 5579 and Sevryuk, Lombardi, and Aquilanti, Phys. Rev. A. 2005, V. 72, No. 3, P. 033201, we defined several partitions of the total kinetic energy of a system of classical particles into terms corresponding to various motion modes. In this work, we study the statistics of these terms for clusters with the number of particles N from 3 to 100 (at randomly selected particle coordinates and velocities). Some new kinetic energy components are defined and studied. Two limiting situations are considered, those of particles of equal masses and particles whose masses vary randomly. With equal masses, the mean values of almost all cluster kinetic energy components are expressed in terms of N with the use of very simple equations.

Published

2008

27. KAM tori: persistence and smoothness

Author

Mikhail B. Sevryuk

Subjects

Floquet theory, Integrable system, Invariance principle, Dynamical systems theory, Kolmogorov–Arnold–Moser theorem, Applied Mathematics, General Physics and Astronomy, Statistical and Nonlinear Physics, Torus, Invariant (physics), Topology, Mathematics::Symplectic Geometry, Mathematical Physics, Mathematical physics, Mathematics

Abstract

Ten open problems in Kolmogorov–Arnold–Moser theory for finite-dimensional dynamical systems are presented and discussed. These problems concern the preservation of frequencies and Floquet exponents of invariant tori of partially integrable systems under small perturbations in the presence of external parameters.

Published

2008

28. The special features of rotationally resolved differential cross sections of the F + H2 reaction at small scattering angles

Author

J. P. Toennies, L. Yu. Rusin, and Mikhail B. Sevryuk

Subjects

Superposition principle, Scattering, Chemistry, Potential energy surface, Physical and Theoretical Chemistry, Atomic physics, Ground state, Collision, Relative amplitude, Differential (mathematics)

Abstract

We studied the nature and collision energy dependence of the maximum that appears in the angular distributions of the HF (v′ = 3) product of the F + H2 (v = 0; j = 0, 1, 2) → H + HF (v′, j′) reaction at small scattering angles θ in the center-of-mass frame. This maximum and its increase as the collision energy increased were discovered in the well-known experiment described by D.M. Neumark, A.M. Wodtke, G.N. Robinson, C.C. Hayden, and Y.T. Lee, J. Chem. Phys. 82 (7), 3045 (1985). In order to determine the nature of the maximum, we performed quantum-mechanical simulation of the reaction on the Stark-Werner ground state potential energy surface at collision energies of 1.84, 2.74, and 3.42 kcal/mol corresponding to the above-mentioned experiment and calculated the vibrationally and rotationally resolved differential cross sections dσv′j′/dΩ of the reaction. The maximum under consideration was found to be due to a superposition of two effects, namely, the absence of HF (v′ = 3; j′) products with large j′ because of energy restrictions and an increase in the relative amplitude of quantum-mechanical oscillations on dσv′j′/dΩ cross sections at small j′ and θ as v′ increased. Oscillations on dσ3j′/dΩ cross sections with small j′ are responsible for the maximum observed.

Published

2007

29. Invariant tori in quasi-periodic non-autonomous dynamical systems via Herman's method

Author

Mikhail B. Sevryuk

Subjects

Physics, Discrete mathematics, Dynamical systems theory, Kolmogorov–Arnold–Moser theorem, Approximations of π, Applied Mathematics, Diophantine equation, Torus, symbols.namesake, symbols, Dissipative system, Discrete Mathematics and Combinatorics, Quasi periodic, Hamiltonian (quantum mechanics), Analysis, Mathematical physics

Abstract

We consider quasi-periodic (with $N$ basic frequencies) non-autonomous perturbations of Hamiltonian, reversible, volume preserving, and dissipative systems. The unperturbed systems possess analytic families of invariant $n$-tori carrying conditionally periodic motions, are allowed to depend on external parameters, and are assumed to satisfy just very weak nondegeneracy conditions. We construct invariant $(n+N)$-tori in perturbed systems following M.R. Herman's approach: additional external parameters are introduced to remove degeneracies and then are eliminated via an appropriate number-theoretical lemma concerning Diophantine approximations of dependent quantities.

Published

2007

30. Few-body quantum and many-body classical hyperspherical approaches to reactions and to cluster dynamics

Author

Leonardo Peroncelli, Gaia Grossi, Federico Palazzetti, Andrea Lombardi, Vincenzo Aquilanti, and Mikhail B. Sevryuk

Subjects

Momentum, Classical mechanics, Computer science, Harmonics, Bound state, Coordinate system, Diagonal, Basis function, Physical and Theoretical Chemistry, Representation (mathematics), Quantum, Hyperspherical approachHyperspherical harmonicsBasis setsHyperangular momentaKinetic energy partitionsMode couplings

Abstract

The hyperspherical method is a widely used and successful approach for the quantum treatment of elementary chemical processes. It has been mostly applied to three-atomic systems, and current progress is here outlined concerning the basic theoretical framework for the extension to four-body bound state and reactive scattering problems. Although most applications only exploit the advantages of the hyperspherical coordinate systems for the formulation of the few-body problem, the full power of the technique implies representations explicitly involving quantum hyperangular momentum operators as dynamical quantities and hyperspherical harmonics as basis functions. In terms of discrete analogues of these harmonics one has a universal representation for the kinetic energy and a diagonal representation for the potential (hyperquantization algorithm). Very recently, advances have been made on the use of the approach in classical dynamics, provided that a hyperspherical formulation is given based on “classical” definitions of the hyperangular momenta and related quantities. The aim of the present paper is to offer a retrospective and prospective view of the hyperspherical methods both in quantum and classical dynamics. Specifically, regarding the general quantum hyperspherical approaches for three- and four-body systems, we first focus on the basis set issue, and then we present developments on the classical formulation that has led to applications involving the implementations of hyperspherical techniques for classical molecular dynamics simulations of simple nanoaggregates.

Published

2006

31. Partial preservation of frequencies in KAM theory

Author

Mikhail B. Sevryuk

Subjects

Integrable system, Kolmogorov–Arnold–Moser theorem, Applied Mathematics, Diophantine equation, Degenerate energy levels, General Physics and Astronomy, Statistical and Nonlinear Physics, Diophantine approximation, Invariant (physics), Hamiltonian system, Dissipative system, Mathematical Physics, Mathematics, Mathematical physics

Abstract

We consider perturbations of moderately degenerate integrable or partially integrable Hamiltonian systems, so that unperturbed invariant n-tori with prescribed frequencies or frequency ratios do not persist, but there is preservation of, say, the first d < n frequencies or their ratios. Lagrangian and lower dimensional tori are treated in a unified way. The proofs are very simple and follow Herman's idea of 1990: we introduce external parameters to remove degeneracies and then eliminate these parameters making use of a suitable number-theoretical lemma concerning Diophantine approximations of dependent quantities. Parallel results for reversible, volume preserving and dissipative systems are also presented.

Published

2006

32. Book Review: Arnold's problems

Author

Mikhail B. Sevryuk

Subjects

Applied Mathematics, General Mathematics

Published

2005

33. Phase-space invariants for aggregates of particles: Hyperangular momenta and partitions of the classical kinetic energy

Author

Vincenzo Aquilanti, Andrea Lombardi, and Mikhail B. Sevryuk

Subjects

Physics, Angular momentum, Classical mechanics, Total angular momentum quantum number, Critical phenomena, Phase space, Angular momentum coupling, Coordinate system, General Physics and Astronomy, Physical and Theoretical Chemistry, Moment of inertia, Kinetic energy

Abstract

Rigorous definitions are presented for the kinematic angular momentum K of a system of classical particles (a concept dual to the conventional angular momentum J), the angular momentum L(xi) associated with the moments of inertia, and the contributions to the total kinetic energy of the system from various modes of the motion of the particles. Some key properties of these quantities are described-in particular, their invariance under any orthogonal coordinate transformation and the inequalities they are subject to. The main mathematical tool exploited is the singular value decomposition of rectangular matrices and its differentiation with respect to a parameter. The quantities introduced employ as ingredients particle coordinates and momenta, commonly available in classical trajectory studies of chemical reactions and in molecular dynamics simulations, and thus are of prospective use as sensitive and immediately calculated indicators of phase transitions, isomerizations, onsets of chaotic behavior, and other dynamical critical phenomena in classical microaggregates, such as nanoscale clusters.

Published

2004

34. Long-Range Interaction in Some Simple Open-Shell Systems, Including Rare-Gas Sulfides: Features of Post-Adiabatic Potentials and Couplings

Author

Lev Yu. Rusin, Mikhail B. Sevryuk, Vincenzo Aquilanti, and Simonetta Cavalli

Subjects

Coupling, Chemistry, Scattering, Ab initio, Schrödinger equation, symbols.namesake, Vibronic coupling, symbols, Physics::Chemical Physics, Physical and Theoretical Chemistry, Atomic physics, Adiabatic process, Quantum, Open shell

Abstract

The first-order post-adiabatic representations in the sense of Klar and Fano (Klar, H.; Fano, U. Phys. Rev. Lett. 1976, 37, 1132−1134) are obtained for two-channel stationary Schrodinger equations describing the interaction of the fluorine and chlorine (in the 2P state) and oxygen and sulfur (in the 3P state) atoms with a number of closed-shell particles, in particular, with rare gases, hydrogen, deuterium, and methane. Information on the adiabatic potentials and the nonadiabatic coupling comes mostly from scattering experiments, although some input from ab initio quantum mechanical calculations is also exploited. Various trends in the behavior of the first-order post-adiabatic coupling are analyzed, and the optimal ways to estimate the smallness of this coupling are discussed. The best measure of the strength of the post-adiabatic coupling of order s is found to be the differences between the respective post-adiabatic potentials of orders s and s + 1. A rigorous proof is given of the fact that post-adiab...

Published

2004

35. Simulation of the reactive scattering of F+D2 on a model family of potential energy surfaces with various topographies: The correlation approach

Author

Lev Yu. Rusin, J. Peter Toennies, and Mikhail B. Sevryuk

Subjects

Correlation, Cross section (physics), Nonlinear system, Scattering, Chemistry, Potential energy surface, General Physics and Astronomy, Statistical physics, Physical and Theoretical Chemistry, Atomic physics, Quantum number, Potential energy, Connection (mathematics)

Abstract

The connection between the salient features of the potential energy surface (PES) and the dynamical characteristics of the elementary collision process is studied using a correlation approach based on quasiclassical trajectory simulations. The method is demonstrated for the reaction F + D2 --D + DF for which the scattering characteristics were calculated on a model family of PES's based on a London-Eyring-Polanyi-Sato-type five-parameter equation. The correlations between the reactive cross section and the vibrational and rotational quantum numbers and the scattering angle of the DF product, and the various parameters of the collinear and noncollinear PES's, such as the location and height of the minimal barrier and the Sato coefficients, are reported. Although usually correlations between two variables suffice, in some cases coefficients of correlation among three variables are required. The role of nonlinear parameter dependencies in computing the correlation coefficients is also considered. The correlation approach makes it possible to examine a large set of potential surfaces without intermediate human control and obtain quantitative information.

Published

2004

36. Effect of the angular dependence of the barrier height on the features of the F+H2 reaction

Author

Lev Yu. Rusin, V. M. Azriel, J. Peter Toennies, and Mikhail B. Sevryuk

Subjects

Surface (mathematics), Chemistry, Scattering, Branching fraction, Product (mathematics), Dynamics (mechanics), General Physics and Astronomy, State (functional analysis), Physical and Theoretical Chemistry, Atomic physics, Chemical reaction, Potential energy

Abstract

The most adequate description of the dynamical behavior of F+H 2 →H+HF, one of the most important model elementary chemical reactions, can be achieved on potential energy surfaces (PES) with a non-collinear transition state configuration. Each such surface is characterized by the particle interaction angle where the minimum of the barrier height is attained. In the present paper, an extended LEPS method where the Sato coefficients are given by a five-parameter expression is proposed and used to examine how the dependence of the barrier height E 0 on the interaction angle γ affects the chemical scattering dynamics. We show that in this model system, the minimum of the dependence E 0 ( γ ) and its shape determine, to a great extent, the total reaction cross-section, the HF( v f ) product branching ratio and the angular distribution of the product scattering.

Published

1998

37. Statistics of energy partitions for many-particle systems in arbitrary dimension

Author

Mikhail B. Sevryuk, Andrea Lombardi, and Vincenzo Aquilanti

Subjects

Normalization (statistics), Particle system, Regular and chaotic dynamics, Euclidean space, Mathematical analysis, FOS: Physical sciences, Regular and chaotic dynamics, energy partitions, hyper spherical coordinates, clusters, Mathematical Physics (math-ph), Kinetic energy, Physical level, hyper spherical coordinates, Mathematics (miscellaneous), Planar, clusters, energy partitions, Mathematical Physics, 53A17, 93C25, 70G10, 70B99, Mathematics

Abstract

In some previous articles, we defined several partitions of the total kinetic energy T of a system of N classical particles in the d-dimensional Euclidean space into components corresponding to various modes of motion. In the present paper, we propose formulas for the mean values of these components in the normalization T=1 (for any d and N) under the assumption that the masses of all the particles are equal. These formulas are proven at the "physical level" of rigor and numerically confirmed for planar systems (d=2) at N from 3 through 100. The case where the masses of the particles are chosen at random is also considered. The paper complements our article of 2008 [Russian J Phys Chem B, 2(6), 947-963] where similar numerical experiments were carried out for spatial systems (d=3) at N from 3 through 100., 34 pages, 4 figures, prepared for Functional Analysis and Other Mathematics

Published

2013

38. A hard-sphere model for the reactions of two diatomic molecules with ionic bond

Author

Lev Yu. Rusin, Mikhail B. Sevryuk, and V. M. Azriel

Subjects

Chemistry, General Physics and Astronomy, Ionic bonding, Halide, Molecule, Hard spheres, Physical and Theoretical Chemistry, Atomic physics, Alkali metal, Diatomic molecule, Excitation

Abstract

We propose an impulsive model for the interaction between two alkali halide molecules. The excitation functions for various channels of the reactions RbBr+RbBr, CsBr+CsBr, RbCl+CsI, and RbI+CsCl obtained within this model exhibit a qualitative agreement with the results of exact quasiclassical trajectory calculations.

Published

1995

39. A wave packet propagation study of inelastic and reactive F+D2 scattering

Author

Gert Due Billing, Mikhail B. Sevryuk, and L. Yu. Rusin

Subjects

Coupling, Deuterium, Opacity, Chemistry, Scattering, Wave packet, General Physics and Astronomy, Physical and Theoretical Chemistry, Atomic physics, Inelastic scattering, Ground state, Excitation

Abstract

We compute the rotationally resolved differential cross sections for F(2P3/2)+D2(v=0,j) inelastic scattering as well as opacity functions for D2 rotational excitation and the reaction F+D2→D+DF. Two values of the collision energy (89.7 and 187 meV) and two initial D2 rotational states (j=0 and j=1) are probed. Four calculation techniques have been compared: the quasiclassical trajectory approach and the Wigner method on the ground state (12A′) surface, wave packet propagation (with the D2 vibrational degree of freedom treated quantum mechanically) on the 12A′ surface, and wave packet propagation on the two coupled surfaces 12A′ and 22A′. The effect of the nonadiabatic spin–orbit coupling on the nonreactive F+D2 scattering is almost negligible, whereas the reaction cross sections in the two‐surface wave packet propagation treatment are considerably smaller than those in the calculations taking into account the ground state surface only.

Published

1995

40. A test of the semiclassical Wigner method for the reaction F + H2 → H + HF

Author

L. Yu. Rusin, Mikhail B. Sevryuk, V. M. Azriel, and G.D. Billing

Subjects

Physics, Langer correction, Branching fraction, Quantum mechanics, Phase space, Potential energy surface, Degrees of freedom (physics and chemistry), General Physics and Astronomy, Semiclassical physics, Physical and Theoretical Chemistry, Atomic physics, Quantum, Rotational energy

Abstract

We compute the vibrationally resolved integral cross sections σ R (ν′), differential cross sections, and opacity functions for the reaction F + H 2 ( ν = 0, j = 0, 1) → H + HF( ν ′, j ′) on the 6SEC potential energy surface by the quasiclassical trajectory technique as well as the Wigner method. In both cases, the Langer correction of the initial H 2 rotational energy is implemented. The results are compared with the recent quasiclassical trajectory calculations on the same surface without the Langer correction and quantum mechanical calculations. It is shown that use of the Wigner phase space functions to describe the H 2 and HF vibrational degrees of freedom reduces the total integral cross sections, smooths the selective HF( ν ′ = 3) forward peak in the HF center-of-mass angular distributions, and dramatically increases the σ R ( ν ′ = 3)/ σ R ( ν ′ = 2) vibrational branching ratio. These results indicate that the disagreements between the quasiclassical trajectory cross sections and the quantum mechanical ones observed in the previous works cannot be minimized by just a proper choice and weighting of the initial conditions in the quasiclassical trajectory calculations.

Published

1995

41. Post-adiabatic approach to atomic and molecular processes: The van der Waals interactions of some open shell systems

Author

Simonetta Cavalli, Mikhail B. Sevryuk, Lev Yu. Rusin, and Vincenzo Aquilanti

Subjects

Van der Waals equation, Chemistry, Van der Waals strain, Van der Waals surface, Context (language use), symbols.namesake, Physics::Atomic and Molecular Clusters, symbols, Van der Waals radius, Physics::Atomic Physics, Chiropractics, Physics::Chemical Physics, Physical and Theoretical Chemistry, van der Waals force, Atomic physics, Adiabatic process, Open shell

Abstract

Various properties of post-adiabatic representations of multichannel Schrodinger equations are described in the general context of adiabatic and classical path approximations as used in atomic and molecular physics. The van der Waals interactions of fluorine, chlorine, and oxygen atoms with rare gases, hydrogen, methane, and hydrogen halides are considered: it is found that in some of these systems, the first-order post-adiabatic scheme exhibits a smaller coupling than the adiabatic representation, thus providing an appropriate choice of the basis functions for a decoupling approximation.

Published

1995

42. Vibrational transition probabilities for the CO molecule trapped in an argon cluster: a semiclassical simulation

Author

Gert Due Billing and Mikhail B. Sevryuk

Subjects

Argon, Chemistry, Icosahedral symmetry, Degrees of freedom (physics and chemistry), General Physics and Astronomy, Semiclassical physics, chemistry.chemical_element, Diatomic molecule, Impurity, Physics::Atomic and Molecular Clusters, Cluster (physics), Molecule, Physical and Theoretical Chemistry, Atomic physics

Abstract

We calculate the 0→1, 1→0, 1→2, 2→1, and 2→3 vibrational transition probabilities of the CO molecule trapped in the center of icosahedral argon clusters with 12, 54, and 146 Ar atoms at various cluster temperatures. The semiclassical scheme has been employed, where the impurity vibrations are quantized while all the other degrees of freedom are treated classically. The transition probabilities increase with the cluster size but exhibit an inverse temperature dependence.

Published

1994

43. KAM theory for lower dimensional tori within the reversible context 2

Author

Mikhail B. Sevryuk

Subjects

Pure mathematics, 70K43, 70H33, Kolmogorov–Arnold–Moser theorem, General Mathematics, Chaotic, FOS: Mathematics, Torus, Dynamical Systems (math.DS), Fixed point, Invariant (mathematics), Mathematics - Dynamical Systems, Mathematics

Abstract

The reversible context 2 in KAM theory refers to the situation where dim Fix G < (1/2) codim T, here Fix G is the fixed point manifold of the reversing involution G and T is the invariant torus one deals with. Up to now, the persistence of invariant tori in the reversible context 2 has been only explored in the extreme particular case where dim Fix G = 0 [M. B. Sevryuk, Regul. Chaotic Dyn. 16 (2011), no. 1-2, 24-38]. We obtain a KAM-type result for the reversible context 2 in the general situation where the dimension of Fix G is arbitrary. As in the case where dim Fix G = 0, the main technical tool is J. Moser's modifying terms theorem of 1967., 21 pages; dedicated to the memory of Vladimir Igorevich Arnold who is so unexpectedly gone

Published

2011

44. Dynamical mechanisms of direct three-body recombination

Author

Lev Yu. Rusin, E. V. Kolesnikova, Mikhail B. Sevryuk, and V. M. Azriel

Subjects

Third body, Chemistry, Chemical physics, Atom, Molecule, Physical and Theoretical Chemistry, Atomic physics, Ion pairs, Impact parameter, Recombination, Rotational energy, Ion

Abstract

Despite the ubiquity of recombination processes in nature and various technologies, presently little is known about the dynamics of these processes. This article reports on a quasi-classical trajectory study of the dynamics of the direct three-body recombination of Cs(+) and Br(-) ions in the presence of a Xe atom at energies of the ion encounter and that of the third body ranging from 0.2 to 10 eV. Several dynamical mechanisms of stabilization of the recombining ion pair have been found. Head-on ion encounters are characterized by two mechanisms of removing the energy from the recombining pair. In the case of nonzero impact parameters of ion encounters, the dynamics leading to the stabilization of the nascent CsBr molecule becomes much more complicated and three new mechanisms appear. They depend mainly on the energy of the ion encounter, on the energy of the collision of the ion pair with the third body, and on the impact parameter of the ion encounter and the impact parameter of the third body. The common feature of all the three mechanisms is the transfer of a fraction of the rotational energy of the recombining pair to the third body. This transfer plays a key role in the stabilization of the molecule. The dynamical peculiarities observed are expected to be common for the recombination of the charged and neutral particles.

Published

2011

45. Simulation of oriented collision dynamics of simple chiral molecules

Author

Mikhail B. Sevryuk, Glauciete S. Maciel, Andrea Lombardi, Federico Palazzetti, and Vincenzo Aquilanti

Subjects

Hydrogen, Chemistry, Scattering, media_common.quotation_subject, Intermolecular force, chemistry.chemical_element, Condensed Matter Physics, Asymmetry, Atomic and Molecular Physics, and Optics, Collision dynamics, Chemical physics, Computational chemistry, Simple (abstract algebra), Intramolecular force, Physical and Theoretical Chemistry, Quantum, media_common

Abstract

With the aim of illustrating computationally the mechanism of chiral discrimination induced by molecular collisions, we present results of extensive classical dynamics simulations of oriented collisions of rare gas atoms with prototypical chiral molecules, such as hydrogen peroxide and hydrogen persulfide. Models for the intermolecular and intramolecular interactions are based on previous quantum chemical calculations. The phenomenon of right-left asymmetry in scattering directions is documented both by exemplary single trajectories and by angular distributions obtained by statistical averagings. © 2010 Wiley Periodicals, Inc. Int J Quantum Chem 00: 000-000, 2010

Published

2011

46. Multiple impacts and energy transfer in a three-body system for noncollinear collisions

Author

Lev Yu. Rusin, Mikhail B. Sevryuk, and V. M. Azriel

Subjects

Chemistry, Energy transfer, Degrees of freedom (physics and chemistry), chemistry.chemical_element, Collision, Diatomic molecule, Xenon, Physics::Atomic and Molecular Clusters, Molecule, Physics::Atomic Physics, Chiropractics, Physics::Chemical Physics, Physical and Theoretical Chemistry, Atomic physics, Nuclear Experiment, Trajectory (fluid mechanics), Energy (signal processing)

Abstract

Within the impulsive framework, the energy transfer processes in collisions of atoms with diatomic molecules are considered. In the case of noncollinear collisions involving multiple impacts between the particles, analytic expressions for the amount of the collision energy transferred to the internal degrees of freedom of the molecule have been derived. The limiting cases of these expressions are the well-known Mahan (a single impact) and Mahan-Shin (collinear collisions) formulas. The efficiency of energy transfer in collisions of cesium halide molecules with xenon atoms has been computed as an example; the results obtained agree well with the data of accurate trajectory calculations.

Published

1993

47. Asymptotic (semiclassical) equivalence for Schrödinger equations with singular potentials and for related systems of two first‐order equations

Author

Mikhail B. Sevryuk, Vincenzo Aquilanti, and Simonetta Cavalli

Subjects

Variables, ORDINARY DIFFERENTIAL-EQUATIONS, COLLINEAR REACTIVE SCATTERING, Differential equation, media_common.quotation_subject, Mathematical analysis, Semiclassical physics, Statistical and Nonlinear Physics, Schrödinger equation, symbols.namesake, Transformation matrix, Singularity, Linear differential equation, symbols, Equivalence (formal languages), Mathematical Physics, media_common, Mathematics

Abstract

The asymptotic equivalence of systems of two ordinary first‐order linear differential equations with complex independent variable and a small parameter at the derivatives is analyzed in the case of arbitrary numbers and multiplicities of turning points and singular points. The set of all the transformation matrices realizing the equivalence is described and a recursive procedure for constructing these matrices is developed. By persistently using the determinant properties of the transformation matrices, the number of integration operations at each step of this procedure is halved compared with the algorithms known before. The theory is specialized to the case of time‐independent one‐dimensional Schrodinger equations with singular potentials. Some generalizations to multichannel Schrodinger equations are also presented.

Published

1993

48. KAM Theory: Quasi-periodicity in Dynamical Systems

Author

Mikhail B. Sevryuk and Hendrik Broer

Subjects

Dynamical systems theory, Kolmogorov–Arnold–Moser theorem, Nowhere dense set, Mathematical analysis, Torus, symbols.namesake, Attractor, symbols, Dissipative system, Uniqueness, Hamiltonian (quantum mechanics), Mathematics::Symplectic Geometry, Mathematics, Mathematical physics

Abstract

We present Kolmogorov–Arnold–Moser (or KAM) Theory regarding typicality of quasi-periodic invariant tori, partly from a historical and partly from a pedagogical point of view. At the same time we aim at a unified approach of the theory in various dynamical settings: the ‘classical’ Hamiltonian setting of Lagrangean tori, the Hamiltonian lower dimensional isotropic tori, the dissipative case of quasi-periodic attractors, etc. Also we sketch the theory of quasi-periodic bifurcations, where resonances cause Cantorization and fraying of the bifurcation sets known from the cases of equilibrium points and periodic orbits. Here the concept of Whitney differentiability plays a central role, which locally organizes the nowhere dense union of persistent quasi-periodic invariant tori, of positive measure. At the level of torus bundles this Cantorization is observed as well, where the geometry of the torus bundles turns out to be persistent. In the meantime we briefly deal with the natural affine structure of quasi-periodic tori, with uniqueness of most of the KAM tori, and with the mechanisms of the destruction of resonant unperturbed tori. Other parts of the theory, such as the Hamiltonian higher

Published

2010

49. Long-range features of the F-HBr and F-HI potential energy surfaces from crossed molecular-beam experiments: a model analysis

Author

J. Peter Toennies, Mikhail B. Sevryuk, and Lev Yu. Rusin

Subjects

Range (particle radiation), Chemistry, Scattering, Hydrogen bromide, General Physics and Astronomy, chemistry.chemical_element, Potential energy, Molecular physics, Crossed molecular beam, chemistry.chemical_compound, Fluorine, Physical chemistry, Hydrogen iodide, Physics::Chemical Physics, Physical and Theoretical Chemistry, Nuclear Experiment

Abstract

Relative differential and integral cross sections for scattering of fluorine atoms by hydrogen bromide and hydrogen iodide have been measured at collision energies from 5 to 175 meV. Treating the experimental data in terms of a single potential of the Lennard-Jones type, we have evaluated the well depths and equilibrium distances of the long-range interaction potentials.

Published

1991

50. Specific Heats of Clusters Near a Phase-Transition: Energy Partitions among Internal Modes

Author

Andrea Lombardi, Mikhail B. Sevryuk, Vincenzo Aquilanti, and Ersin Yurtsever

Subjects

Phase transition, Molecular dynamics, Classical mechanics, Chemistry, Degrees of freedom (physics and chemistry), General Physics and Astronomy, Partition (number theory), Statistical physics, Decoupling (cosmology), Physical and Theoretical Chemistry, Energy (signal processing)

Abstract

This Letter proposes a way to answer the question of how energy is shared by internal degrees of freedom, when nanoaggregates are heated and undergo phase transitions. Microcanonical molecular dynamics simulations of clusters of 13 and 55 atoms are assisted by our analysis of energy partitions in terms of contributions connected with groups of degrees of freedom of the nanoaggregates. The merit of the partition is shown to be the effective decoupling of modes, demonstrating its role as an indicator of the phase transitions and its perspective use for statistical mechanical approaches by the identification of active degrees of freedom.

Published

2006