Theoretical and Experimental Studies of the Gas-Liquid Interface

Packwood, Daniel Miles

January 2010

A theoretical model describing the motion of a small, fast rare gas atom as it passes over a liquid surface is developed and discussed in detail. A key feature of the model is its reliance on coarse-grained capillary wave and local mode descriptions of the liquid surface. Mathematically, the model is constructed with several concepts from probability and stochastic analysis. The model makes predictions that are quantitative agreement with neon-liquid surface scattering data collected by other research groups. These predictions include the dominance of single, rather than multiple, neon-liquid surface collision dynamics, an average of 60 % energy transfer from a neon atom upon colliding with a non-metallic surface, and an average of 25 % energy transfer upon colliding with a metallic surface. In addition to this work, two other investigations into the gas-liquid interface are discussed. The results of an experimental investigation into the thermodynamics of a gas flux through an aqueous surface are presented, and it is shown that a nitrous oxide flux is mostly due to the presence of a temperature gradient in the gas-liquid interface. Evidence for a reaction between a carbon dioxide flux and an ammonia monolayer on an aqueous surface to produce ammonium carbamate is also found. The second of these is an investigation into the mechanism of bromine production from deliquesced sodium bromide aerosol in the presence of ozone, and involves a sensitivity and uncertainty analysis of the computer aerosol kinetics model MAGIC. It is shown that under dark, non-photolytic conditions, bromine production can be accounted for almost exclusively by a reaction between gas-phase ozone and surface-bound bromide ions. Under photolytic conditions, bromine production instead involves a complicated interplay between various gas-phase and aqueous-phase reactions.

liquid surface

gas-liquid interface

gas-liquid collisions

local mode

capillary wave

irreversible thermodynamics

non-equilibrium thermodynamics

aerosol

MAGIC

Analytické řešení difrakce na planárních periodických strukturách / Analytical solution of diffraction by planar periodic structures

Kuchařík, Jan

January 2018

In my research work, I study diffraction by planar periodic structures (diffraction grating). In the first chapter, I try to familiarize the importance of diffraction gratings in spectroscopy. The second chapter explains the basic principle of diffraction without involving difficult mathematical tools. In the third chapter, I deduce Fourier modal method from Maxwell equations, a modern mathematical approach used for calculating the electromagnetic response of diffraction. The most important part of my work consists of the fourth and fifth chapter. At first, I try to utilize Fourier modal method for deriving formulas involving just 0th and (-1)st diffraction orders. Because of the unreasonable difficulty of uncovered formulas, I decided to consider only a special case - so-called Littrow configuration, in which the solution can be superposed from symmetric and antisymmetric couples of rays. I further develop so-called Local modal method - very inaccurate, but mathematically fairly simple, and discuss its physical limitations. Whole work is finished by the sixth chapter, which compares accurate computations gained from simulation and derived analytical formulas for both methods.

"Expanded" local mode approach and isotopic effect in polyatomic molecules / Approche du mode local "étendu" et effet isotopique dans des molécules polyatomiques

Fomchenko, Anna

18 September 2014

Dans cette thèse, sur la base de l'approche du mode local "étendu" et de la théorie générale de la substitution isotopique, nous obtenons un ensemble de relations analytiques simples entre les paramètres spectrocopiques (fréquences harmoniques, coefficients d'anharmonicité, paramètres rovibrationels, différents types de paramètres d'interaction de Fermi et de Coriolis) des molécules de CH2D2, CH3D et CHD3. Tous ces paramètres sont exprimés en termes de relations simples à partir des paramètres spectroscopiques de la molécule mère CH4. Des calculs tests avec des relations isotopiques montrent que même sans introduire d'informations majeures sur les espèces isotopiques, les résultats numériques de ces calculs sont en bon accord avec les données expérimentales et les calculs ab initio. A partir de le théorie des opérateurs de perturbation et des propriétés de symétrie des molécules axiales XYZ3 (C3v), nous déterminons des formules générales permettant la détermination des paramètres spectroscopiques sous la forme de fonctions des paramètres structuraux et des paramètres de la fonction potentiel intramoléculaire. Nous présentons aussi une approche permettant la détermination du hamiltonien de molécules polyatomiques qui permet de résoudre le problème de la description de la surface d'énergie potentielle via la construction et la diagonalisation d'une matrice hamiltonienne de grande dimension. / In this thesis, on the base of the "expanded", local mode approach and general isotopic substitution theory we obtain sets of simple analytical relations between spectroscopic parameters (harmonic frequencies, anharmonic coefficients, ro-vibrational parameters, different kinds of Fermi and Coriolis-type interaction parameters) of the CH2D2, CH3D and CHD3 molecules. All of them are expressed as simple functions of spectroscopic parameters of the mother CH4 molecule. Test calculations with the isotopic relations show that even without including prior informations about the isotopic species, numerical results of calculations are in a good agreement both with experimental data and results of ab initio calculations. On the base of operators perturbation theory and the symmetry properties of the axially symmetric XYZ3 (C3v) type molecules, we derive general formulae for the determination of the spectroscopic parameters in the form of functions of structural parameters and parameters of the intramolecular potential function. We present also an approach for determination of the Hamiltonian of polyatomic molecules that allows to solve the problem of potential energy surface determination via the construction and the diagonalization of a Hamiltonian matrix of large dimension.

Spectroscopie moléculaire

Molécule de méthane

Espèces deutérées

Le modèle mode local

Relations isotopiques

Fonction potentiel intramoléculaire

Molecular spectroscopy

Methane molecule

Deuterated species

Local mode model

Isotopic relations

Rotational and vibrational parameters

Intramolecular potential function

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