Temperature Programmed Desorption and Infrared Spectroscopic Studies of Interfacial Hydrogen Bonds for Small Molecules Adsorbed on Silica and Within Metal Organic Frameworks

Abelard, Joshua Erold Robert

15 May 2017

Hydrogen bonds are arguably the most important reversible intermolecular forces. However, surprisingly few studies of their fundamental nature at the gas-surface interface have been performed. Our research investigated sulfur mustard (HD) adsorption by characterizing interfacial hydrogen bonding and dispersion forces for the simulant molecules 2-chloroethyl ethyl sulfide (2-CEES) and methyl salicylate on well-characterized hydroxyl-functionalized surfaces (silica and UiO-66). Our approach utilized infrared spectroscopy to study specific surface-molecule interactions and temperature-programmed desorption to measure activation energies of desorption. 2-CEES has two polar functional groups, the chloro and thioether moieties, available to accept hydrogen bonds from free surface silanol groups. Diethyl sulfide and chlorobutane were investigated to independently assess the roles of the chloro and thioester moieties in the overall adsorption mechanism and to explore the interplay between the charge transfer and electrostatic contributions to total hydrogen bond strength. The results indicate that both SiOH---Cl and SiOH---S hydrogen bonds form when 2-CEES adsorbs to silica or hydroxylated UiO-66. However, a more stable configuration in which both polar groups interact simultaneously with adjacent silanol groups likely does not form. A systemaic study of chloroalkanes revealed that dispersion forces involving the methylene units in 2-CEES contribute to nearly half of the total activation energy for desorption from silica. Methyl salicylate possesses aromatic, hydroxyl, and ester functional groups, each of which is a potential hydrogen bond acceptor. We found that uptake on silica is mainly driven by the formation of carbonyl-silanol and hydroxyl-silanol hydrogen bonds with additional contributions from weaker interactions. In an effort to learn more about the SiOH---π bond, the adsorption of simple substituted benzene derivatives on silica was investigated to probe the effects of electron withdrawing and donating substituents. Results indicate that the substituted benzene derivatives adsorb to silica via a cooperative effect involving SiOH---π hydrogen bonds and additional substituent-surface interactions. The strength of the SiOH---π bond is enhanced by electron donating groups and weakened by electron withdrawing groups. / Ph. D.

silica

desorption

MOF

hydrogen bond

surface

spectroscopic

TPD

Probing unoccupied electronic states in aqueous solutions

Näslund, Lars-Åke

January 2004

<p>Water is one of the most common compounds on earth and is essential for all biological activities. Water has, however, been a mystery for many years due to the large number of unusual chemical and physical properties, e.g. decreased volume during melting and maximum density at 4 °C. The origin of the anomalies behavior is the nature of the hydrogen bond. This thesis will presented an x-ray absorption spectroscopy (XAS) study to reveal the hydrogen bond structure in liquid water.</p><p>The x-ray absorption process is faster than a femtosecond and thereby reflects the molecular orbital structure in a frozen geometry locally around the probed water molecules. The results indicate that the electronic structure of liquid water is significantly different from that of the solid and gaseous forms. The molecular arrangement in the first coordination shell of liquid water is actually very similar as the two-hydrogen-bonded configurations at the surface of ice. This discovery suggests that most molecules in liquid water have two-hydrogen-bonded configurations with one donor and one acceptor hydrogen bond compared to the four-hydrogen-bonded tetrahedral structure in ice. This result is controversial since the general picture is that the structure of liquid water is very similar to the structure of ice. The results are, however, consistent with x-ray and neutron diffraction data but reveals serious discrepancies with structures based on current molecular dynamics simulations. The two-hydrogen-bond configuration in liquid water is rigid and heating from 25 °C to 90 °C introduce a minor change in the hydrogen-bonded configurations. Furthermore, XAS studies of water in aqueous solutions show that ion hydration does not affect the hydrogen bond configuration of the bulk. Only water molecules in the close vicinity to the ions show changes in the hydrogen bond formation. XAS data obtained with fluorescence yield are sensitive enough to resolved electronic structure of water molecules in the first hydration sphere and to distinguish between different protonated species. Hence, XAS is a useful tool to provide insight into the local electronic structure of a hydrogen-bonded liquid and it is applied for the first time on water revealing unique information of high importance.</p>

x-ray absorption

x-ray absorption spectroscopy

XAS

NEXAFS

water

liquid water

aqueous solution

hydrogen bond

hydrogen bond network

local geometry

Physics

Fysik

Probing unoccupied electronic states in aqueous solutions

Näslund, Lars-Åke

January 2004

Water is one of the most common compounds on earth and is essential for all biological activities. Water has, however, been a mystery for many years due to the large number of unusual chemical and physical properties, e.g. decreased volume during melting and maximum density at 4 °C. The origin of the anomalies behavior is the nature of the hydrogen bond. This thesis will presented an x-ray absorption spectroscopy (XAS) study to reveal the hydrogen bond structure in liquid water. The x-ray absorption process is faster than a femtosecond and thereby reflects the molecular orbital structure in a frozen geometry locally around the probed water molecules. The results indicate that the electronic structure of liquid water is significantly different from that of the solid and gaseous forms. The molecular arrangement in the first coordination shell of liquid water is actually very similar as the two-hydrogen-bonded configurations at the surface of ice. This discovery suggests that most molecules in liquid water have two-hydrogen-bonded configurations with one donor and one acceptor hydrogen bond compared to the four-hydrogen-bonded tetrahedral structure in ice. This result is controversial since the general picture is that the structure of liquid water is very similar to the structure of ice. The results are, however, consistent with x-ray and neutron diffraction data but reveals serious discrepancies with structures based on current molecular dynamics simulations. The two-hydrogen-bond configuration in liquid water is rigid and heating from 25 °C to 90 °C introduce a minor change in the hydrogen-bonded configurations. Furthermore, XAS studies of water in aqueous solutions show that ion hydration does not affect the hydrogen bond configuration of the bulk. Only water molecules in the close vicinity to the ions show changes in the hydrogen bond formation. XAS data obtained with fluorescence yield are sensitive enough to resolved electronic structure of water molecules in the first hydration sphere and to distinguish between different protonated species. Hence, XAS is a useful tool to provide insight into the local electronic structure of a hydrogen-bonded liquid and it is applied for the first time on water revealing unique information of high importance.

x-ray absorption

x-ray absorption spectroscopy

XAS

NEXAFS

water

liquid water

aqueous solution

hydrogen bond

hydrogen bond network

local geometry

Physics

Fysik

Hydrogen-bonding motifs for non-covalent synthesis

Pearson, Jem M.

January 2013

This work describes the design and synthesis of a set of four organic molecules that are intended to hydrogen-bond to each other in a pairwise manner. The four hydrogen-bonding units, termed ‘A’, ‘B’, ‘C’ and ‘D’, when placed in solution together, are designed so that A binds only to B, and C binds only to D. Each unit does not bind to itself, nor to either of the other two units to which binding is not intended. For example, A binds to B, but not to A, C, or D. Each unit contains an array of four hydrogen-bonds for strong binding to its partner, is designed to be as rigid as possible, as non-tautomeric as possible, and utilises a staggered non-symmetrical architecture. Of the four intended compounds, three were successfully synthesised (A, B and D). Units B and D were soluble in CDCl₃, but Unit A was not. Therefore, the design and synthesis of Unit A was amended, and two variants of Unit A that are both soluble in CDCl₃ were successfully synthesised. ¹H NMR binding experiments were performed between Unit B and each of the two variants of Unit A. Their binding behaviour was described. A binding constant could not be calculated because the units did not bind in a 1:1 fashion.

541

Polymérisation organocatalysée de monomères hétérocycliques par voie supramoléculaire / Supramolecular organocatalyzed polymerization of heterocyclic monomers

Thomas, Coralie Marine

05 July 2012

Il a été montré que les organocatalyseurs donneurs ou accepteurs de liaison hydrogène permettent de promouvoir de nombreuses transformations chimiques. Dans le domaine des réactions de polymérisations organocatalysées (notamment les polymérisations par ouverture de cycle, ROP), des dérivés de thiourée, les hexafluoro-alcools, les amidines ont déjà été décrits comme catalyseurs supramoléculaires de la polymérisation des esters cycliques. Nous avons développé un nouveau système catalytique basé sur l’activation par liaison hydrogène du monomère d’une part, de l’amorceur et la chaîne en croissance d’autre part. Ce nouveau couple de catalyseurs met en jeu des dérivés du phénol ou des ammoniums (donneurs de liaisons hydrogène) associés à des amines tertiaires ou amidine (accepteurs de liaisons hydrogène). Grâce au caractère vivant de la polymérisation, les polymères créés ont une masse molaire contrôlée et une dispersité étroite. / It has been shown that hydrogen-bonding (donor or acceptor) organocatalysts can promote different chemical transformations. In organocatalysed polymerizations (including Ring opening polymerization, ROP), several H-bonding compounds such as thiourea derivatives, hexafluoro alcohols, or amidines proved to be effective in the polymerization of cyclic esters. We developed a new catalytic system based on the activation through hydrogen bond of the monomer, initiator and growing chain. These new catalysts involve phenol derivatives or ammoniums (hydrogen bond donors) associated to tertiary amines or amidine (hydrogen bond acceptors). Due to the living character of the polymerization, synthesized polyesters controlled molar masses and narrow dispersities.

Organocatalyse

Liaison hydrogène

Polymérisation

Esters cycliques

Rmn

Organocatalysis

Hydrogen bond

Polymerization

Cyclic esters

Nmr

Absorção de CO2 por líquidos iônicos: uma abordagem termodinâmica e espectroscópica / CO2 absorption by ionic liquids: a thermodynamic and spectroscopic approach.

Lepre, Luiz Fernando

13 December 2017

Esta tese trata da utilização de líquidos iônicos como solventes para a absorção de CO2, e busca relacionar o efeito das diferentes interações intermoleculares existentes no próprio solvente, assim como as interações estabelecidas com o gás, na capacidade de absorção do dióxido de carbono. Uma vez que as propriedades macroscópicas de líquidos iônicos estão diretamente associadas a sua estrutura e às interações entre as espécies iônicas, procura-se relacionar propriedades macroscópicas termodinâmicas com evidências microscópicas por espectroscopia. Nesse sentido, será possível estabelecer relações entre a estrutura local dos íons e a capacidade de absorção do gás, ampliando, dessa maneira, o estudo sobre a utilização destes materiais como solventes absorvedores de CO2. Utilizando uma dupla abordagem experimental, uma termodinâmica e outra espectroscópica, esta tese foi dividida em três partes. Na primeira, o efeito do CO2 na estrutura de líquidos iônicos foi investigado por espectroscopia Raman. Com o intuito de sondar o domínio polar dos líquidos iônicos, foi estudado o efeito da pressão de CO2 na posição das bandas mais características dos ânions. Diferente dos resultados reportados na literatura, a maioria dos quais obtidos via simulação por dinâmica molecular, foi observada uma modificação das interações iônicas no domínio polar dos líquidos iônicos. Esta modificação estrutural provocada pelo CO2 mostrou-se dependente da intensidade das interações entre cátions e ânions do próprio líquido. A segunda etapa explora o efeito de grupos éter de um polímero, PEO, nas propriedades de [N4111][NTf2]. Valores negativos de entalpia de mistura, &#916;mixH < 0, sugerem interações favoráveis entre [N4111][NTf2] e PEO. Espectros Raman confirmam uma associação favorável entre o cátion N4111+ e PEO, onde cadeias de PEO provavelmente envolvem o cátion. Estas interações refletem diretamente na dinâmica do sistema, apresentando forte dependência com o tamanho da cadeia polimérica. O aumento da quantidade de CO2 absorvida com o aumento da quantidade de PEO na mistura foi explicado por interações mais favoráveis entre o gás e o polímero, como mostrado pelo aumento das negativas entalpias de solvatação do CO2 nas misturas. Por fim, a terceira parte investiga o efeito do ânion C(CN)3- na capacidade de absorção de CO2 por [C4C1Im][Ac]. Misturas de [C4C1Im][Ac] e [C4C1Im][C(CN)3] tiveram suas propriedades físico-químicas registradas, observando uma diminuição da viscosidade do fluido com a adição de C(CN)3-. Este resultado foi atribuído a uma reorganização da rede de ligações de hidrogênio. A presença do ânion C(CN)3- não afeta significativamente a reação química do CO2 com [C[N4111][NTf2]C1Im][Ac] (constante de equilíbrio é mantida), mas diminui a constante de Henry, apontando para maiores absorções físicas do gás. Apesar de não afetar a absorção química de CO2 por [C4C1Im][Ac], a presença do ânion C(CN)3- melhora consideravelmente a transferência de massa, aumentando a fluidez do líquido absorvente. / This thesis is aimed at discussing the use of ionic liquids as solvents for the absorption of CO2 and seeks to relate the effect of different intermolecular interactions in the solvent itself, as well as the interactions established with the gas, on the carbon dioxide absorption capacity. Since the macroscopic properties of ionic liquids are directly associated with their structure and the interactions between their ions, it is sought to relate macroscopic thermodynamic properties with microscopic spectroscopic evidences. Therefore, it will be possible to establish relations between the local structure of the ions and the absorption capacity of the gas, thus expanding the study on the use of these materials as CO2-absorbing solvents. Using a double experimental approach, one thermodynamic and the other spectroscopic, this thesis was divided into three parts. At first, the effect of CO2 on the structure of ionic liquids was investigated by Raman spectroscopy. In order to probe the polar domain of ionic liquids, the effect of CO2 pressure on the most characteristic bands of anions was investigated. Unlike the results reported in the literature, most of them obtained through molecular dynamics simulation, it was observed a modification on the ionic interactions in the ionic liquids polar domain. This structural change driven by CO2 revealed to be dependent on the intensity of cation-anion interactions of the liquid itself. The second step of this thesis explores the effect of ether groups of a polymer, PEO, on the properties of [N4111][NTf41112]. Negative values of mixing enthalpy, &#916;mixH < 0, suggest favorable interactions between [N4111][NTf2] and PEO. Raman spectra results also suggest a favorable interaction between N4111+ cation and PEO, where PEO chains probably wrap the cation. These interactions directly reflect on the dynamics of the system, which has a strong dependence on the polymer chain size. The increase of absorbed CO2 by increasing the amount of PEO in the mixture was explained by more favorable interactions between the gas and the polymer, as revealed by the increase in the negative values of CO2 solvation enthalpy in the mixtures. Lastly, the third part investigates the effect of adding C(CN)3- anion on the CO2 absorption capacity of [C4C1Im][Ac]. Studying the physicochemical properties of [C4C1Im][Ac] mixed with [C4C1Im][C(CN)3] it was observed a decrease in the fluid viscosity upon the addition of C(CN)3-. This behavior was attributed to a reorganization of the [C4C1Im][Ac] hydrogen bond network due to the presence of C(CN)3- anion. The presence of C(CN)3- anion does not affect significantly the chemical reaction between CO2 and [C4C1Im][Ac] (chemical equilibrium is kept constant), but Henrys law constants decrease, pointing to greater physical absorption of the gas. Although not affecting the CO2 chemical uptake by [C4C1Im][Ac], the presence of the C(CN)3- anion considerably improves mass transfer, increasing the fluidity of the absorbent liquid.

CO2

CO2

Constante de equilíbrio

Equilibrium constant

Hydrogen bond

Ionic liquids

Ligação de hidrogênio

Líquidos iônicos

Polímeros

Polymers

Absorção de CO2 por líquidos iônicos: uma abordagem termodinâmica e espectroscópica / CO2 absorption by ionic liquids: a thermodynamic and spectroscopic approach.

Luiz Fernando Lepre

13 December 2017

Esta tese trata da utilização de líquidos iônicos como solventes para a absorção de CO2, e busca relacionar o efeito das diferentes interações intermoleculares existentes no próprio solvente, assim como as interações estabelecidas com o gás, na capacidade de absorção do dióxido de carbono. Uma vez que as propriedades macroscópicas de líquidos iônicos estão diretamente associadas a sua estrutura e às interações entre as espécies iônicas, procura-se relacionar propriedades macroscópicas termodinâmicas com evidências microscópicas por espectroscopia. Nesse sentido, será possível estabelecer relações entre a estrutura local dos íons e a capacidade de absorção do gás, ampliando, dessa maneira, o estudo sobre a utilização destes materiais como solventes absorvedores de CO2. Utilizando uma dupla abordagem experimental, uma termodinâmica e outra espectroscópica, esta tese foi dividida em três partes. Na primeira, o efeito do CO2 na estrutura de líquidos iônicos foi investigado por espectroscopia Raman. Com o intuito de sondar o domínio polar dos líquidos iônicos, foi estudado o efeito da pressão de CO2 na posição das bandas mais características dos ânions. Diferente dos resultados reportados na literatura, a maioria dos quais obtidos via simulação por dinâmica molecular, foi observada uma modificação das interações iônicas no domínio polar dos líquidos iônicos. Esta modificação estrutural provocada pelo CO2 mostrou-se dependente da intensidade das interações entre cátions e ânions do próprio líquido. A segunda etapa explora o efeito de grupos éter de um polímero, PEO, nas propriedades de [N4111][NTf2]. Valores negativos de entalpia de mistura, &#916;mixH < 0, sugerem interações favoráveis entre [N4111][NTf2] e PEO. Espectros Raman confirmam uma associação favorável entre o cátion N4111+ e PEO, onde cadeias de PEO provavelmente envolvem o cátion. Estas interações refletem diretamente na dinâmica do sistema, apresentando forte dependência com o tamanho da cadeia polimérica. O aumento da quantidade de CO2 absorvida com o aumento da quantidade de PEO na mistura foi explicado por interações mais favoráveis entre o gás e o polímero, como mostrado pelo aumento das negativas entalpias de solvatação do CO2 nas misturas. Por fim, a terceira parte investiga o efeito do ânion C(CN)3- na capacidade de absorção de CO2 por [C4C1Im][Ac]. Misturas de [C4C1Im][Ac] e [C4C1Im][C(CN)3] tiveram suas propriedades físico-químicas registradas, observando uma diminuição da viscosidade do fluido com a adição de C(CN)3-. Este resultado foi atribuído a uma reorganização da rede de ligações de hidrogênio. A presença do ânion C(CN)3- não afeta significativamente a reação química do CO2 com [C[N4111][NTf2]C1Im][Ac] (constante de equilíbrio é mantida), mas diminui a constante de Henry, apontando para maiores absorções físicas do gás. Apesar de não afetar a absorção química de CO2 por [C4C1Im][Ac], a presença do ânion C(CN)3- melhora consideravelmente a transferência de massa, aumentando a fluidez do líquido absorvente. / This thesis is aimed at discussing the use of ionic liquids as solvents for the absorption of CO2 and seeks to relate the effect of different intermolecular interactions in the solvent itself, as well as the interactions established with the gas, on the carbon dioxide absorption capacity. Since the macroscopic properties of ionic liquids are directly associated with their structure and the interactions between their ions, it is sought to relate macroscopic thermodynamic properties with microscopic spectroscopic evidences. Therefore, it will be possible to establish relations between the local structure of the ions and the absorption capacity of the gas, thus expanding the study on the use of these materials as CO2-absorbing solvents. Using a double experimental approach, one thermodynamic and the other spectroscopic, this thesis was divided into three parts. At first, the effect of CO2 on the structure of ionic liquids was investigated by Raman spectroscopy. In order to probe the polar domain of ionic liquids, the effect of CO2 pressure on the most characteristic bands of anions was investigated. Unlike the results reported in the literature, most of them obtained through molecular dynamics simulation, it was observed a modification on the ionic interactions in the ionic liquids polar domain. This structural change driven by CO2 revealed to be dependent on the intensity of cation-anion interactions of the liquid itself. The second step of this thesis explores the effect of ether groups of a polymer, PEO, on the properties of [N4111][NTf41112]. Negative values of mixing enthalpy, &#916;mixH < 0, suggest favorable interactions between [N4111][NTf2] and PEO. Raman spectra results also suggest a favorable interaction between N4111+ cation and PEO, where PEO chains probably wrap the cation. These interactions directly reflect on the dynamics of the system, which has a strong dependence on the polymer chain size. The increase of absorbed CO2 by increasing the amount of PEO in the mixture was explained by more favorable interactions between the gas and the polymer, as revealed by the increase in the negative values of CO2 solvation enthalpy in the mixtures. Lastly, the third part investigates the effect of adding C(CN)3- anion on the CO2 absorption capacity of [C4C1Im][Ac]. Studying the physicochemical properties of [C4C1Im][Ac] mixed with [C4C1Im][C(CN)3] it was observed a decrease in the fluid viscosity upon the addition of C(CN)3-. This behavior was attributed to a reorganization of the [C4C1Im][Ac] hydrogen bond network due to the presence of C(CN)3- anion. The presence of C(CN)3- anion does not affect significantly the chemical reaction between CO2 and [C4C1Im][Ac] (chemical equilibrium is kept constant), but Henrys law constants decrease, pointing to greater physical absorption of the gas. Although not affecting the CO2 chemical uptake by [C4C1Im][Ac], the presence of the C(CN)3- anion considerably improves mass transfer, increasing the fluidity of the absorbent liquid.

CO2

Constante de equilíbrio

Ligação de hidrogênio

Líquidos iônicos

Polímeros

CO2

Equilibrium constant

Hydrogen bond

Ionic liquids

Polymers

Estabilidade isomérica e ligações de hidrogênio em agregados e líquidos moleculares / Isomeric stabibility and hydrogen bonds in clusters and molecular liquids

Fileti, Thaciana Valentina Malaspina

09 August 2006

Neste trabalho, estamos interessados na descrição da estabilidade isomérica de moléculas isoladas e em agregados, assim como em propriedades eletrônicas de agregados moleculares em fase gasosa e estruturas com ligação de hidrogênio em fase líquida. Na primeira investigação, estabilidade isomérica, estudamos a estabilidade relativa dos isômeros "C IND.2v", "C IND.3v" e "C IND.s" da molécula de "AlP IND.3" isolada. Analisamos tanto a estrutura conformacional, quanto a energética dos três isômeros e depois de submetermos as estruturas mais estáveis a cálculos sofisticados de química quântica, extrapolamos os resultados obtidos para as energias dos isômeros ao limite de base completa. Chegamos µa conclusão que o isômero "C IND.3v" é o menos estável dos três investigados, e que os isômeros "C IND.2v" e "C IND.s" apresentam-se como estados quase-degenerados com uma diferença de energia de 'DA ORDEM DE' 1,6 kcal/mol. Ainda pensando na estabilidade isomérica,investigamos os agregados HCN...HOH e "H IND.2"O...HCN, também em fase gasosa. Através de cálculos ab initio obtivemos a estrutura e energética dos dois agregados. Comparamos a energia dos dois agregados depois de obtermos, através de métodos altamente acurados de correlação eletrônica no limite de base completa, e obtivemos que o agregado "H IND.2"O...HCN é o mais estável por 'DA ORDEM DE'1,5 kcal/mol. Na segunda parte de nosso trabalho, investigamos as modificações sofridas em agregados moleculares quando estes são formados em diferentes ambientes, o gasoso e o líquido. Primeiro, analisamos as diferenças nos agregados de pirazina ("N IND.2" "C IND.4" "H IND.4") e água (1:1 e 1:2), através de comparação da estrutura e propriedades eletrônicas obtidas em fase gasosa através de otimização de geometria e em fase líquida, obtidos da simulação computacional Monte Carlo Metropolis. Para as estruturas 1:1 comparamos os resultados nos dois ambientes através da estrutura, energia e momento de dipolo. Para os agregados 1:2 comparamos adicionalmente as contribuições energéticas de muitos corpos e a cooperatividade nos dois ambientes. Todos os resultados nos mostram que os agregados em fase gasosa são cerca de 30% mais estáveis que os agregados do líquido, tanto para os agregados 1:1 quanto para os agregados 1:2. Ao ¯final do trabalho, analisamos as modificações sofridas no espectro eletrônico do formaldeído ("H IND.2"CO) quando este se encontra em ambiente aquoso. Analisamos especificamente o deslocamento da banda de energia referente à transição n- > "'pi'POT.*" deste espectro quando consideramos 1, 2 e 3 moléculas de água solvatando o formaldeído e também quando incluímos toda a primeira camada de solvatação, 18 moléculas de água, todas inclusas explicitamente no cálculo quântico. Adicionalmente, fizemos estimativas para a contribuição da dispersão de London e da relaxação da ligação C=O no deslocamento da banda n- > "'pi'POT.*" do formaldeído solvatado / In this work, we study the isomeric stability of isolated molecules and molecular clusters. We study the change of some electronic properties of molecular clusters in gas and liquid phases. The first application is the relative isomeric stability of isolated AlP3 in C2v, C3v and Cs symmetries. We analyze the conformational structure and the total energy of the three isomers using sophisticated quantum chemistry calculations and using CCSD(T)/cc-pVXZ (X = 2, 3, 4 and 5) level and extrapole to the infinite basis set limit. The locations of the two states on the potential energy hyper-surface are obtained and show that they represent well-defined and stable isomers. We also investigate the HCN...HOH and H2O...HCN clusters in gas phase, using ab initio calculations to obtain the optimized structure of these two molecular clusters. We present a systematic study of the stability of the H2O...HCN and HCN...HOH complexes calculating the binding energy of both systems using the aug-cc-pVXZ basis sets with X=2,3,4 and extending the results to the infinite limit. At the best theoretical level, CCSD(T), the H2O...HCN cluster is more stable than HCN...HOH by ~ 1.5 kcal/mol. In the second part of our work, we investigate the electronic modifications in molecular clusters due to the different environments of these clusters, the gas and the liquid phases. We analyze the pyrazine-water clusters (1:1 and 1:2) obtained in gas and liquid phases and compare the structure and electronic clusters properties. For the 1:1 pyrazine-water clusters we compare the structures, total energy and dipole moments. For the 1:2 pyrazine-water clusters we analyze the many-body contributions to the interaction energy and cooperativity. All results show that the gas phase clusters have interaction energies that are around 30% of the liquid clusters. Finally, we analyze the absorption electronic spectrum of formaldehyde in liquid water. We specifically analyze the shift of the n-pi* electronic transition. We consider 1, 2, 3 and 18 water molecules solvating the formaldehyde, all explicitaly included in the TD-DFT calculations. Additionally, we make estimates of the London dispersion contribution and C=O stretching effects in the shift of the n-pi* electronic transition of formaldehyde in water.

Calculos quânticos

Hydrogen bond

Ligação de hidrogênio

Liquidos moleculares

Molecular liquids

Quantun mechanic calculations

Efeitos de ligações de hidrogênio em propriedades de aglomerados e de líquidos moleculares / Effects of hydrogen bonding on properties of clusters and molecular liquids

Moreno, Roberto Rivelino de Melo

17 February 2003

A influência da formação de ligações de hidrogênio (LHs) em sistemas moleculares é investigada analisando-se as propriedades de aglomerados próton-ligados e de moléculas em solventes próticos. As estruturas supermoleculares dos aglomerados são obtidas por otimização de geometria com diferentes métodos quânticos ab initio. Por sua vez, as estruturas supermoleculares dos solventes dependem de condições termodinâmicas e, portanto, são obtidas utilizando-se técnicas de simulação Monte Carlo, em que as interações intermoleculares são parametrizadas pelos potenciais de Lennard-Jones e de Coulomb. Os efeitos decorrentes da formação de LHs nos aglomerados moleculares são analisados a partir de suas prioridades: estabilidades, espectros vibracionais, constante rotacionais e dipolos elétricos. Estas propriedades são calculadas usando-se métodos perturbativos (MBPT/CC) e teoria do funcional da densidade(DFT). Para as moléculas solvatadas em meio líquido, os efeitos das LHs são analisadas na interação soluto-solvente duranto o processo de equilíbrio conformacional de fuufural em solventes próticos. A contribuição da interação do soluto com o meio também é investigada no espectro de absorção UV-vis do sistema furfural/água. Os resultados destes estudos mostram que a formação de LHs é importante para explicar o comportamento de algumas propriedades de sistemas moleculares próton-ligados, principalmente de aglomerados. No caso de sistemas em fase líquida, as LHs dependem, basicamente, do caráter prótico e da polaridade do solvente, propriedades que concorrem para a estabilização de possíveis formas conformacionais da molécula do soluto. / The influence of hydrogen bond formation in molecular systems is investigated analyzing the properties of both hydrogen-bonded clusters and molecules in protic solvents. The super-molecular structures of the cluster are obtained by optimizing the geometries with different ab initio quantum methods. On the other hand, the super-molecular structures of the solvents depend on thermodynamic conditions and, so, are obtained by using Monte Carlo simulation techniques, where the intermolecular interactions are accounted for the Lennard-Jones and Coulomb pair-potentials. The effects due to H-bond formation in the molecular clusters are analyzed from their properties: stabilities, vibrational spectra, rotational constants, and electric dipoles. These properties are calculated using perturbation methods (MBPT/CC) and density functional theory (DFT). For the molecules in liquid solvents, the H-bond effects are analyzed in the solute-solvent interaction during the conformational equilibrium process of furfural in protic solvents. The contribution of the interaction of the solute with the medium is also investigated in the UV-vis absorption spectrum of the furfural/water system. The results from these studies show that the H-bonding process is important to account for the behavior of some properties of H-bonded molecular systems, mainly of clusters. In the case of liquid-phase systems, the H-bonds depend basically on both the protic nature and polarity of the solvent, properties that come together to stabilize possible conformational forms of the solute molecules.

Aglomerados moleculares

Conformational equilibrium

Equilíbrio conformacional

Hydrogen bond

Ligação de hidrogênio

Molecular clusters

\"Transferência de carga e ligação de hidrogênio intramolecular em derivados de 9-aminoacridina\" / \"Intramolecular charge and hydrogen bon transfer in 9-aminoacridine derivatives\"

Pereira, Robson Valentim

25 August 2006

Neste trabalho, o corante 9-aminoacridina foi derivatizado com compostos vinílicos que possuem grupos retiradores de elétrons. A incorporação destes leva à mudanças nas propriedades fotofísicas dos derivados, tais como deslocamentos para regiões de menor energia nos espectros de absorção e emissão, sugerindo a presença de transferência de carga intramolecular (ICT). Os estudos de fluorescência resolvida no tempo confirmam este processo para os derivados. Este estado ICT possui um tempo formação na faixa de 150 – 300 ps e um tempo de vida entre 1 – 3 ns, que depende do solvente. Os derivados que apresentam pelo menos um grupo carbonila como retirador de elétron, possuem um tempo de vida longo na faixa de 8 –10 ns, atribuído à emissão do enol, formado a partir da conjugação estendida por ponte de hidrogênio. A polimerização destes derivados com o ácido metacrílico promoveram mudanças em suas propriedades fotofísicas estacionárias e resolvidas no tempo devido à quebra da conjugação &#61552; estendida. Este fato é ilustrado pelos espectros de absorção e emissão que mostram bandas estruturadas, deslocadas para a região de maior energia e um decaimento monoexponencial, semelhante ao observado com 9-aminoacridina. Anisotropia de fluorescência resolvida no tempo mostra que nos copolímeros o tempo de relaxação rotacional do corante é muito sensível à mudança conformacional do poli (ácido metacrílico) com o pH, possibilitando assim o estudo da dinâmica deste polímero em solução aquosa. / In this work, the dye 9-aminoacridine was derivatized with vinylic compounds containing electron withdrawing groups. The incorporation of these groups leads to changes in the photophysical properties of the dye, such a red shift in the absorption and emission spectra, suggesting the presence of intramolecular charge transfer (ICT) effect. Time-resolved studies have confirmed such process in all derivatives. This ICT state has a risetime in the range 150 – 300 ps and a fluorescence lifetime between 1 – 3 ns, that depends of the solvent. The derivatives with at least one carbonyl group as electron withdrawing, have an additional lifetime in the range of 8 –10 ns, attributed to the enol emission formed by the extended conjugation. The polimerization of these derivatives with methacrylic acid induces changes in the stationary and time-resolved properties of the dye due to the breaking of the extended &#61552;&#61472;conjugation. This fact is illustrated by the absorption and emission spectra that show structured bands with a blue shift, and a monoexponencial decay, similar to the behavior of 9- aminoacridine. Time-resolved fluorescence anisotropy of the bound dye shows that the copolymers have a segment relaxation of the chain is very sensitive to the change in the conformational shape of poly (methacrylic acid) with pH, and such a process is well indicated by following the rotational relaxation of the dye.

fluorescence

fluorescencia

intramolecular charge transfer

intramolecular hydrogen bond

ligação de hidrogênio intramolecular

transferência de carga intramolecular