Specific Heat Studies on the Water Confined in Mesopore's Zeolite

Pan, Yu-Ta

23 June 2006

Water is a continuous source of fascination to scientist because of its many counterintuitive low-temperature properties. Although the stable from of water at low temperature is crystalline, liquid water can also exist below the melting point. Many people study the interesting phenomenon of water at low temperature and it is found that two critical points may even coexist in a single component liquid [1]. The other properties of water, like melting point, viscosity, compressibility, self-diffusion constant have also been studied below low temperature [2-4]. Now, we want to take the advantage of the equipment we have in our laboratory to measure the temperature dependence of Cp of water confined in different scale of nano-pores. This is also the beginning for people to study the thermodynamic properties of water confined in nano-pores. In addition, I have learned a lot, such as to understand LabView graphical programming language, the skill to measure AC specific heat, DSC specific heat, and to set up TGA. It will be helpful for me in the future, I think.

Confined Water

Zeolite

Nanometer

Specific Heat

Structure, Dynamics And Thermodynamics Of Confined Water Molecules

Kumar, Hemant

10 1900

This thesis deals with several aspects of the structure and dynamics of water molecules confined in nanoscopic pores. Water molecules confined in hydrophobic nanocavities exhibit unusual structural and dynamic properties. Confining walls of single-wall carbon nanotubes (SWCNTs) promote strong inter-water hydrogen bonding which in turn leads to several novel structural, dynamic and thermodynamic features not found in bulk water. Confined water molecules form ordered hydrogen-bonded networks, exhibit exceptionally high flow rates as compared to conventional flow in pipes, allow fast proton conduction and exhibit various other anomalous properties. Proteins are known to exploit some of the properties of confined water to perform certain physiological functions. Various properties of confined water can also be exploited in the design of nanofludic devices such as those for desalination and flow sensors. In addition, water molecules confined in SWCNTs and near graphene sheets serve as model systems to study various effects of confinement on the properties of liquids. In this thesis, we present the results of detailed molecular dynamics simulation studies of confined water molecules. In chapter 1, we summarize the findings of existing simulations and experimental studies of bulk and confined water molecules. We also highlight the significance of studying the structure and dynamics of confined water molecules in biological and biotechnological applications. Chapter 2 provides a brief ac-count of the methods and techniques used to perform the simulations described in subsequent chapters of the thesis. We also present a brief overview of the methods used to extract physical properties of water molecules from simulation data, with emphasis on the Two Phase Thermodynamics (2PT) method which we have used to compute the entropy of confined and bulk water molecules. In chapter 3, we discuss the thermodynamics of water entry in SWCNTs of various diameters. Experiments and computer simulations demonstrate that water spontaneously fills the interior of a carbon nanotube. Given the hydrophobic nature of the interior of carbon nanotubes and the strong confinement produced by narrow nanotubes, the spontaneous entry of water molecules in the pores of such nanotubes is surprising. To gain a quantitative thermodynamic understanding of this phenomenon, we use the recently developed Two Phase Thermodynamics (2PT) method to compute translational and rotational entropies of water molecules confined in SWCNTs and show that the increase in energy of a water molecule inside the nanotube is compensated by the gain in its rotational entropy. The confined water is in equilibrium with the bulk water and the Helmholtz free energy per water molecule of confined water is the same as that in the bulk within the accuracy of the simulation results. A comparison of translational and rotational spectra of water molecules confined in carbon nanotubes with those of bulk water shows significant shifts in the positions of spectral peaks that are directly related to the tube radius. These peaks are experimentally accessible and can be used to characterize water dynamics from spectroscopy experiments. We have also computed the free-energy transfer when a bulk water molecule enters a SWCNT for various temperatures and carbon-water interactions. We show that for reduced carbon-oxygen interaction, the free energy transfer is unfavourable and the SWCNT remains unoccupied for significant periods of time. As the temperature is increased, the free energy of confined water becomes unfavourable and reduced occupancy of water is observed. Bulk water exhibits many anomalous properties. No single water model is able to reproduce all properties of bulk water. Different empirical water models have been developed to reproduce different properties of water. In chapter 4, a comparative study of the structure, dynamics and thermodynamic proper-ties of water molecules confined in narrow SWCNTs, obtained from simulations using several water models including polarizable ones, is presented. We show that the inclusion of polarizability quantitatively affects the nature of hydro-gen bonding which governs different properties of water molecules. The SPC/E water model is shown to reproduce results in close agreement with those from polarizable water models with much less computational cost. In chapter 5, we report results obtained from simulations of the properties of water confined in the space between two planar surfaces. We consider three cases: two graphene surfaces, two Boron Nitride (BN) surfaces and one graphene and one BN surface. This is the first detailed study of the behaviour of water near extended BN surfaces. We show that the hydrophilic nature of the BN surface leads to several interesting effects on the dynamics of water molecules near it. We have observed a change in the activation energy, extracted from the temperature dependence of the translational and rotational dynamics, near 280K. This change in activation energy coincides with a change in the structure of the confined sheet of water, indicated by a sudden change in energy. We have also found signatures of glassy dynamics at low temperatures for all three cases, the glassy effects being the strongest for water molecules confined between two BN sheets. These results are similar to those of earlier studies in which novel phases of water have been found for water molecules confined between other surfaces at high pressure. In chapter 6, we have described our observation of a novel phenomenon exhibited by water molecules flowing through a SWCNT under a pressure gradient. We have shown that the flow induces changes in the orientation of the water molecules flowing through the nanotube. In particular, the dipole moments of the water molecules inside the nanotube get aligned along the axis of the nanotube under the effect of the flow. With increasing flow velocities, the net dipole moment first increases and eventually saturates to a constant value. This behaviour is similar to the Langevin theory of paramagnetism with the flow velocity acting as an effective aligning field. Preferential entry of water molecules with dipole moments pointing inward is shown to be the main cause of this effect. This observation provides a way to control the dipolar alignment of water molecules inside nano-channels, with possible applications in nanofluidic devices. Chapter 7 contains a summary of our main results and a few concluding re-marks.

Confined Water Molecules

Nano Confined Water

Confined Water

Molecular Dynamics Simulations

Bulk Water Molecules

Hydrophobicity

Carbon Nanotube Confined Water Molecules

Confined Water Molecular Dynamics

Confined Water Molecular Structure

Confined Water Molecular Thermodynamics

Slit Pore

Confined Water Polarizability

Water Models

Molecular Physics

WETTING TRANSITIONS AT NANOSTRUCTURED SURFACES

Seyed, Yazdi Jamileh

12 September 2011

Shape of a droplet atop a surface heterogeneity at a nanoscale. Small aqueous droplets on homogeneous surfaces, surrounded by a reservoir of vapor are inherently unstable. In contact with supersaturated vapor, the drops will keep growing until they coalesce and form a contiguous aqueous phase. Alternatively, if vapor pressure is below that of the droplets, the droplets gradually evaporate. Departing from this common picture, when nanoscale droplets sit above hydrophilic patches on a heterogeneous surface, at certain conditions they can maintain a stable volume, determined by the pertinent contact angle and the size of the patches. Only the region under the droplet perimeter controls the contact angle, which in turn determines the drops curvature for given volume and the vapor pressure of the liquid in the drop. The drop size may therefore stop changing when its base just covers the hydrophilic patch. The finite range of water-substrate interactions, however, blurs the patch boundaries hence the nanodrop geometry varies with the patch size in a gradual manner. We use molecular simulations to examine this dependence on graphene-like surfaces with topological heterogeneity as complementing studies of chemical heterogeneity (John Ritchie, Master Thesis, VCU, 2010). We measure the microscopic analogue of the contact angle of aqueous nanodrops above circular hydrophilic or hydrophobic patches of varied size. For both the chemically and topographically heterogeneous surfaces, the results confirm the contact angle of a nanodroplet can be predicted by the local Cassie-Baxter mixing relation applied to the area within the interaction range from the drop’s perimeter, which, in turn, enables predictions of condensation and saturated vapor pressure above nanopatterned hydrophilic/hydrophobic surfaces. Switchable nanowetting dynamics. Understanding the dynamic response of contact angle on switchable hydrophobic-hydrophilic surfaces is key to the design of nanofluidic and optical devices. We use molecular dynamics simulation for water droplets with different number of molecules on a molecularly smooth and corrugated substrate. We monitored the relaxation of the droplet geometry in response to a change in surface hydrophobicity. From the time correlation function for the height of the drop’s center of mass we estimate the rates of relaxation for wetting/dewetting processes following the change between hydrophobic and hydrophilic character of the surface. On molecularly smooth surfaces, we find similar forward/backward rates revealing insignificant hysteresis. Calculations on corrugated surfaces, however, reveal quite different relaxation times for forward (Cassie state to Wenzel state) and reverse processes. The observed hysteresis is associated with different friction forces between the droplet and the surface during advancing and receding processes. We calculate the friction coefficient of the corrugated surface for the forward process following the increase in surface hydrophilicity. We compare continuum hydrodynamic (HD) and molecular kinetic theories (MKT) for calculation of the friction coefficient. Although the small size of our system suggests the use of molecular description of the surface, incorporated in MKT, we obtain essentially equal friction coefficients from both theories. This information indicates an overlap between continuum hydrodynamics and molecular dynamics regimes, with both the HD and MKT theories being applicable at the nanoscopic lengthscales we consider. Water dynamics inside nanospheres. Chemical nature of a spherical confinement has significant effect on dynamics of water molecules outside the cage. In a separate study we examined the effect of chemical nature of the cage on the dynamics of water molecules inside the cage. Calculations have been made for variety of time correlation functions of water in four different sizes of spherical hydrophobic/hydrophilic confinements, Cx x=320, 500, 720, 1500 based “hollow buckyballs”, with different spherical pore diameters. Calculated water hydrogen bond lifetimes, diffusion coefficients and rotational relaxation times in these systems reveal a distinctly different water dynamics compared to interfacial water dynamics outside the cage: interestingly we find insignificant changes in time scales for water dynamics in hydrophilic and hydrophobic carbon cages. Even adding partial charges to hydrophilic confinement did not make a big effect on results compared to hydrophobic case. These findings are suggesting that in highly symmetric confinement water molecules do not care about the type of interaction with the wall because of cancellation of forces in different directions.

Heterogeneity

Contact angle

Cassie state

Wenzel state

Confined water

Chemistry

Physical Sciences and Mathematics

Nanotubes d’imogolite et propriétés de l’eau confinée : organisation, structure et dynamique / Imogolite nanotubes and properties of confined water : organization, structure and dynamics

Amara, Mohamed Salah

15 December 2014

Ce travail de thèse concerne l'étude des propriétés structurales et de confinement des nanotubes inorganiques d’imogolite. Ces nanotubes d’alumino-silicate et/ou germanate existent sous forme mono- et double-parois avec des diamètres de l’ordre du nanomètre. Nous avons étudié la synthèse de ces nanotubes et le contrôle de leur organisation, leur structure et leur déformation, ainsi que les propriétés de l’eau confinée.Dans les deux premiers chapitres, nous présentons un état de l’art sur les nanotubes d’imogolite et les différentes méthodes expérimentales utilisées. Dans le troisième chapitre, dédié à la synthèse des nanotubes et aux propriétés de nanotubes hybrides, nous présentons une nouvelle méthode de synthèse qui permet d’augmenter d’un ordre de grandeur la longueur des nanotubes double-parois et nous démontrons l’affinité du bromopropanol, une molécule organique, avec des nanotubes hybrides méthylés.Dans le chapitre suivant, nous nous focalisons sur la détermination de la structure atomique des différents nanotubes d’imogolite, naturels et synthétiques, à base de silicium ou de germanium, mono- et double-parois. Les résultats issus des modèles de minimisation géométrique développés sont confrontés, avec succès, à ceux de diffusion des rayons X expérimentaux aux petits et aux grands angles. Le contrôle de l’auto-organisation des nanotubes en poudre est présenté dans le cinquième chapitre. On y analyse de plus la déformation de la base des nanotubes selon leur état d’auto-organisation.Dans le dernier chapitre, nous décrivons le phénomène de déshydratation des imogolites. En combinant les résultats de diffusion des rayons X et de diffusion inélastique des neutrons, nous proposons la séquence de déshydratation suivante : eau externe ‒ eau confinée au centre de tubes ‒ eau liée. Ces deux derniers types d’eau présentent des caractéristiques spécifiques au niveau des modes de translation et de libration. / This work is dedicated to the study of the structure and to the confinement properties of water in imogolite nanotubes. These aluminosilicate (germanate) inorganic nanotubes exist as single (SW) and double-walled (DW) nanotubes with diameters in the nanometer range. This study concerns the synthesis of imogolite nanotubes, the control of their self-assembling, their structure and deformation, and the properties of confined water.In the first two chapters, we present the state of art on the subject and we describe the different experimental methods used in this work. The third chapter is dedicated to the synthesis of the nanotubes and the properties of hybrid nanotubes. We first present a new method of synthesis allowing the increase of an order of magnitude of the length of double-walled nanotubes; secondly, we demonstrate the affinity of the organic molecule bromopropanol with the methylated hybrid nanotubes.Next chapter focuses on the determination of the atomic structure of different types of imogolite: natural and synthetic, silicon or germanium-based, SW and DW. Results are obtained from computational models based on a geometrical structure minimization, in agreement with the results of small- and wide-angle X-Ray scattering experiments.In the next chapter, we explain how to control the self-assembling and organization of imogolites in powder. Moreover, we analyze the shape deformation of the nanotubes according to their organization.In the last chapter, we describe the behavior of confined water molecules in the imogolite powder as a function of temperature. By combining X-Ray and inelastic neutron scattering techniques, we propose the following sequence for dehydration: external water ‒ confined water in the tube center ‒ bounded water. Dynamical properties of confined and bounded waters are found to be drastically different.

Nanotubes

Imogolite

Organisation

Structure

Déformation

Eau confinée

Dynamique

Nanotubes

Imogolite

Organization

Structure

Deformation

Confined water

Dynamics

Estudo dielétrico da interação da água com substâncias hidrofílicas em baixas temperaturas / Dielectric study of water near hydrophilic surfaces at low temperatures

Moreira, Maria Rejane

29 September 2014

O propósito deste trabalho é aumentar o conhecimento existente sobre as interações dielétricas da água confinada em materiais hidrofílicos, no regime de baixas temperaturas. Os materiais hidrofílicos (sílica gel, gesso, colágeno e álcool polivinílico - PVA) foram analisados com os recursos disponíveis na técnica de Espectroscopia de Impedância - permissividade dielétrica e impedância elétrica. Como objetivo especifico procurou-se estabelecer experimentalmente o papel das ligações hidrogênio nos processos de condução observados na água confinada e verificar a existência da transição dinâmica da água super-resfriada em T = -45ºC (228K). As substâncias examinadas possuem redes ou cadeias moleculares, com grupos polares superficiais capazes de se ligarem às moléculas de água por meio de ligações hidrogênio. Em espaços restritos de natureza hidrofílica, a água pode ser super-resfriada além do ponto de nucleação homogênea, permanecendo líquida para temperaturas inferiores a 0ºC. O entendimento de sistemas envolvendo materiais hidrofílicos - tais como sólidos, géis e macromoléculas - e a água, contribui para o desenvolvimento de novos materiais e para o entendimento dos sistemas vivos. De acordo com os resultados obtidos a condução dos íons na água confinada se dá por meio da rede formada, via ligações hidrogênio, entre as moléculas de água e a cadeia dos materiais. O espectro elétrico dos materiais estudados exibe dois processos de condução, comuns a todas as substâncias. O primeiro, é influenciado pelo nível de hidratação das amostras e está relacionado as moléculas de água distantes das superfícies. O segundo, é próprio da água confinada e possui tempos de relaxação elétricos com transições observadas em -60ºC (210K) na sílica gel, e -45ºC nos outros materiais. Também constatou-se que o tamanho da cadeia polimérica do PVA altera a dinâmica do confinamento de água: cadeias de menor peso molecular não são capazes de gerar sítios que propiciem o confinamento da água. / This work aims to increase the existing knowledge on the dielectric interactions of water confined in hydrophilic materials at low temperatures. The hydrophilic materials (silica gel, gypsum, collagen and polyvinyl alcohol - PVA) were studied with the available functions of Impedance Spectroscopy - dielectric permittivity and electrical impedance. The specific goal of this thesis is to establish the role of hydrogen bonds in the conduction processes observed in confined water and to verify the existence of the supercooled water dynamic crossover at T = -45 ºC (228K). The chosen substances have molecular chains or networks with polar surface groups connected to water molecules through hydrogen bonds. When confined in small geometries, water does not crystallize and can be supercooled bellow its homogeneous nucleation temperature. This allows the indirect investigation of supercooled confined water. The studies of systems involving hydrophilic materials - such as solids, gels and macromolecules - and water, contributes to the development of new materials and to the understanding of living systems. This study demonstrated that the conduction in the confined water occurs through the network formed by hydrogen bonds between water molecules and the chain materials. The impedance spectra of all material exhibits two conduction processes common to all the analyzed samples. While the level of hydration of the samples can influence the process of higher frequencies, the one found in lower frequencies is independent of the amount of water in the samples. The first was associated to bulk water molecules and the second is related to confined water and show the expected dynamic crossover. In addition, the size of the PVA polymeric chain alters the dynamics of water: lower molecular weight polymers are not capable of displaying the supercooled dynamic crossover.

Água confinada

Confined water

Espectroscopia de Impedância

Hydrogen bonds

Hydrophilic molecules

Impedance spectroscopy

Ligações hidrogênio

Substâncias hidrofílicas

Estudo dielétrico da interação da água com substâncias hidrofílicas em baixas temperaturas / Dielectric study of water near hydrophilic surfaces at low temperatures

Maria Rejane Moreira

29 September 2014

O propósito deste trabalho é aumentar o conhecimento existente sobre as interações dielétricas da água confinada em materiais hidrofílicos, no regime de baixas temperaturas. Os materiais hidrofílicos (sílica gel, gesso, colágeno e álcool polivinílico - PVA) foram analisados com os recursos disponíveis na técnica de Espectroscopia de Impedância - permissividade dielétrica e impedância elétrica. Como objetivo especifico procurou-se estabelecer experimentalmente o papel das ligações hidrogênio nos processos de condução observados na água confinada e verificar a existência da transição dinâmica da água super-resfriada em T = -45ºC (228K). As substâncias examinadas possuem redes ou cadeias moleculares, com grupos polares superficiais capazes de se ligarem às moléculas de água por meio de ligações hidrogênio. Em espaços restritos de natureza hidrofílica, a água pode ser super-resfriada além do ponto de nucleação homogênea, permanecendo líquida para temperaturas inferiores a 0ºC. O entendimento de sistemas envolvendo materiais hidrofílicos - tais como sólidos, géis e macromoléculas - e a água, contribui para o desenvolvimento de novos materiais e para o entendimento dos sistemas vivos. De acordo com os resultados obtidos a condução dos íons na água confinada se dá por meio da rede formada, via ligações hidrogênio, entre as moléculas de água e a cadeia dos materiais. O espectro elétrico dos materiais estudados exibe dois processos de condução, comuns a todas as substâncias. O primeiro, é influenciado pelo nível de hidratação das amostras e está relacionado as moléculas de água distantes das superfícies. O segundo, é próprio da água confinada e possui tempos de relaxação elétricos com transições observadas em -60ºC (210K) na sílica gel, e -45ºC nos outros materiais. Também constatou-se que o tamanho da cadeia polimérica do PVA altera a dinâmica do confinamento de água: cadeias de menor peso molecular não são capazes de gerar sítios que propiciem o confinamento da água. / This work aims to increase the existing knowledge on the dielectric interactions of water confined in hydrophilic materials at low temperatures. The hydrophilic materials (silica gel, gypsum, collagen and polyvinyl alcohol - PVA) were studied with the available functions of Impedance Spectroscopy - dielectric permittivity and electrical impedance. The specific goal of this thesis is to establish the role of hydrogen bonds in the conduction processes observed in confined water and to verify the existence of the supercooled water dynamic crossover at T = -45 ºC (228K). The chosen substances have molecular chains or networks with polar surface groups connected to water molecules through hydrogen bonds. When confined in small geometries, water does not crystallize and can be supercooled bellow its homogeneous nucleation temperature. This allows the indirect investigation of supercooled confined water. The studies of systems involving hydrophilic materials - such as solids, gels and macromolecules - and water, contributes to the development of new materials and to the understanding of living systems. This study demonstrated that the conduction in the confined water occurs through the network formed by hydrogen bonds between water molecules and the chain materials. The impedance spectra of all material exhibits two conduction processes common to all the analyzed samples. While the level of hydration of the samples can influence the process of higher frequencies, the one found in lower frequencies is independent of the amount of water in the samples. The first was associated to bulk water molecules and the second is related to confined water and show the expected dynamic crossover. In addition, the size of the PVA polymeric chain alters the dynamics of water: lower molecular weight polymers are not capable of displaying the supercooled dynamic crossover.

Água confinada

Espectroscopia de Impedância

Ligações hidrogênio

Substâncias hidrofílicas

Confined water

Hydrogen bonds

Hydrophilic molecules

Impedance spectroscopy

Estudo da adsorção de monocamadas de água em gipsita(010) através de óptica não linear / Water monolayer adsorption on Gypsum (010) investigated by nonlinear optics

Santos, Jaciara Cássia de Carvalho

23 August 2017

Filmes de água cobrem a maior parte das superfícies em condições ambientes. O estudo dessas interfaces é crucial em biologia e em ciência dos materiais. No entanto, o completo entendimento da adsorção da água e de suas complexas redes de ligações de hidrogênio ainda não foi alcançado. Somente recentemente possuímos técnicas com a sensibilidade e seletividade para estudar estas superfícies até a última camada atômica. A espectroscopia por geração de soma de frequências (SFG) é uma técnica óptica não linear que fornece o espectro vibracional de moléculas em interfaces, sem contribuição do volume do material. A técnica SFG foi utilizada para estudar a estrutura interfacial das moléculas de água estrutural na face livre (010) do cristal natural gipsita (CaSO4 2H2O) e a adsorção de água na mesma à temperatura ambiente. Os espectros SFG na face livre (010), em atmosfera inerte, apresentaram um arranjo com anisotropia azimutal das moléculas de água estrutural com a presença de grupos OH ligados à superfície e grupos OH livre sem formar ligação de hidrogênio, apontando para fora da superfície. O arranjo anisotrópico das moléculas na face (010) é diferente daquele para as moléculas de água no volume do cristal. A adsorção de água foi estudada em equilíbrio com vapor de água em vários valores de umidade relativa. A água adsorvida na gipsita (010) também apresenta um arranjo anisotrópico, porém, diferentemente da água estrutural na superfície livre do cristal, esta apresenta um menor grau de ordenamento e suprime consideravelmente a presença de grupos OH livre. Os resultados experimentais são analisados em conjunto com simulações por dinâmica molecular ab initio realizadas por colaboradores. As simulações apresentaram boa concordância qualitativa e quantitativa com os resultados experimentais, permitindo fazer a atribuição dos espectros vibracionais experimentais, e fornecendo informações difíceis de se obter dos experimentos, como a distribuição orientacional das moléculas de água na interface e sua dinâmica de difusão espacial. / Water films cover most of surfaces under ambient conditions. The study of these interfaces is crucial in biology and materials science. However, a complete understanding of water adsorption and its complex hydrogen bonding networks has not yet been achieved. Only recently we have techniques with the sensitivity and selectivity to study these surfaces to the last atomic layer. Sum-frequency generation (SFG) is a non-linear optical technique that provides the vibrational spectrum of molecules at interfaces, without contribution from the bulk. This technique was used to study the interfacial structure of neat (010) face of Gypsum (CaSO4 2H2O) single crystals and water adsorption on the (010) face at room temperature. The SFG spectra for the neat Gypsum face (010), in inert atmosphere, presented azimuthally anisotropy arrangement of the structural water molecules with the presence of OH groups bound to the surface and free OH groups pointing out of the surface. The arrangement of water molecules on the face (010) is anisotropic but different from that of the water molecules in the bulk crystal. Water adsorption was studied in equilibrium with water vapor at several values of relative humidity. The adsorbed water also exhibited an anisotropic arrangement, however, unlike the structural water, it presents a lower ordering and the free OH groups are strongly suppressed. The experimental results are analyzed together with ab initio molecular dynamics simulations performed by collaborators. The simulations presented good qualitative and quantitative agreement with the experimental results, elucidating the assignment of the experimental vibrational spectra and yielding information that would be difficult to get from the experiments, such as the orientational distribution of interfacial water molecules and their spatial diffusion dynamics.

Adsorção de água

Água confinada

Confined water

Espectroscopia vibracional

Geração de soma de frequências

Gipsita

Gypsum

Sum frequency generation

Vibrational Spectroscopy

Water adsorption

Structure And Dynamics Of Interfacial And Confined Water

Malani, Ateeque Ahmad Abdul Gaffar

03 1900

Understanding the structure and dynamics of molecularly thin films or the state of water confined to nanoscale dimensions is an active field of research and has wide applications in areas ranging from biology to geology. The issues concern fundamental aspects related to the manner in which a substrate influences the organization of water, origin of forces present when water is confined to nanoscale dimensions, and the influence on the structure and dynamics of water adjacent to a surface. The focus of this thesis lies in examining the thermodynamics and transport properties of interfacial and confined water. As a prelude to studying the structure of water confined between two mica surfaces, we first investigated the structuring of water adjacent to a single mica surface using grand canonical Monte Carlo (GCMC) simulations. The adsorption isotherm reveals three distinct stages as the relative vapor pressure in increased. The derived film thickness, isotherm shape, and heats of adsorption are in excellent agreement with recent experimental data. Our study does not support the 2D ice hypothesis and indicates that beyond the first adsorbed layer water is liquid-like. The characteristics of water confined to nanometer dimensions between two hydrophilic surfaces are investigated to assess the influence of chemical functionality of the hydrophilic surface on the structure of confined water. Our study shows that hydration of potassium ions on the mica surface has a strong influence on the water structure and solvation force response of confined water. In contrast to the disrupted hydrogen bond network observed for water confined between mica surfaces, water between silica surfaces is able to retain its hydrogen bond network displaying bulk-like structural features down to surface separations as small as 0.45 nm. An oscillatory solvation force response is observed only for water confined between silica surfaces. We evaluate and contrast the water density, dipole moment distributions, pair correlation functions and the solvation forces as a function of the surface separation. Recent experimental studies have shown that even for subnanometer confinement, the shear viscosity of water between mica surfaces is only three times larger than the free water viscosity. The dynamics of confined water between mica surfaces is evaluated using molecular dynamics simulations. Our analysis shows that the residence time for water in the contact layer is about two orders of magnitude larger than water in the central bulk-like regions between the surfaces. The K+ ions have a strong influence on the dynamics of confined water, leading to a decoupling in the translation and orientational motions. Our analysis also shows the presence of orientational jump dynamics in the contact layer near the mica surface. We also investigate the influence of confinement on the hydration characteristics of NaCl solutions both as a function of the salt concentration and the surface separation, H between graphite surfaces. A hydration limit is defined as the concentration at which a rapid drop in the hydration number is observed with increasing salt concentration. Despite a high degree of confinement, ions are able to form a quasi two-dimensional hydration shell between the two surfaces. The hydration number, reduces to about 4.15 at a pore width of H =8 A, when compared with the bulk hydration number of 6.25. In many practical situations, surfaces that are separated by an intervening fluid can be dissimilar giving rise to the so called Janus interface. In order to probe the fluid structure in such systems, we studied non-polar fluids confined between two asymmetric surfaces. By varying the degree of asymmetry between the two surfaces a wide variety of adsorption situations are examined using GCMC simulations and a mean field lattice model. The degree of asymmetry is found to influence the presence of frozen phases and can also support co-existing liquid and solid phases.

Interfacial Water

Water - Interfacial Properties

Water Structure

Water - Thermodynamics

Water - Transport Properties

Confined Water

Water Adsorption

Chemical Engineering

Molecular Arrangement, Electronic Structure and Transport Properties in Surfactant Gel- and Related Systems Studied by Soft X-ray and Dielectric Spectroscopy

Gråsjö, Johan

January 2013

This thesis concerns studies of aqueous soft matter systems, especially surfactant micelle systems. The aim has been to study the molecular arrangement and electronic structure of the constituents of, as well as transport properties in such a system. The molecular arrangement and electronic structure has been studied by means of X-ray absorption spectroscopy (XAS) and resonant inelastic X-ray spectroscopy (RIXS). The transport properties have been investigated by low-frequency dielectric spectroscopy (LFDS) and small angle X-ray scattering (SAXS) as well as a theoretical modelling. The latter was based on Fick’s laws of the release from binary surfactant system and was validated by experiments. The RIXS and XAS measurements show the electronic structure in bulk water and the influence of the chemical surrounding of the water molecule in bulk water and of the water molecules confined in a micelle lattice. The spectra are highly dependent on the molecular arrangement in such systems. For glycine and sodium polyacrylate RIXS and XAS spectra show features which are unique for carboxyl and carboxylate groups and such measurements can thus be used for fingerprinting. The LFDS and SAXS measurements show a strong correlation between structure in a surfactant/poly-ion system and apparent mobility of surfactants. This conclusion is in line with earlier observations. By the theoretical modelling a predictive model for the surfactant release from a binary surfactant micelle system has been obtained and the importance of different factors for surfactant release has been further clarified.

surfactants

surfactant/poly-ion gel

water

confined water

XAS

RIXS

dielectric spectroscopy

SAXS

pKa

transport

Fick’s law

Estudo da adsorção de monocamadas de água em gipsita(010) através de óptica não linear / Water monolayer adsorption on Gypsum (010) investigated by nonlinear optics

Jaciara Cássia de Carvalho Santos

23 August 2017

Filmes de água cobrem a maior parte das superfícies em condições ambientes. O estudo dessas interfaces é crucial em biologia e em ciência dos materiais. No entanto, o completo entendimento da adsorção da água e de suas complexas redes de ligações de hidrogênio ainda não foi alcançado. Somente recentemente possuímos técnicas com a sensibilidade e seletividade para estudar estas superfícies até a última camada atômica. A espectroscopia por geração de soma de frequências (SFG) é uma técnica óptica não linear que fornece o espectro vibracional de moléculas em interfaces, sem contribuição do volume do material. A técnica SFG foi utilizada para estudar a estrutura interfacial das moléculas de água estrutural na face livre (010) do cristal natural gipsita (CaSO4 2H2O) e a adsorção de água na mesma à temperatura ambiente. Os espectros SFG na face livre (010), em atmosfera inerte, apresentaram um arranjo com anisotropia azimutal das moléculas de água estrutural com a presença de grupos OH ligados à superfície e grupos OH livre sem formar ligação de hidrogênio, apontando para fora da superfície. O arranjo anisotrópico das moléculas na face (010) é diferente daquele para as moléculas de água no volume do cristal. A adsorção de água foi estudada em equilíbrio com vapor de água em vários valores de umidade relativa. A água adsorvida na gipsita (010) também apresenta um arranjo anisotrópico, porém, diferentemente da água estrutural na superfície livre do cristal, esta apresenta um menor grau de ordenamento e suprime consideravelmente a presença de grupos OH livre. Os resultados experimentais são analisados em conjunto com simulações por dinâmica molecular ab initio realizadas por colaboradores. As simulações apresentaram boa concordância qualitativa e quantitativa com os resultados experimentais, permitindo fazer a atribuição dos espectros vibracionais experimentais, e fornecendo informações difíceis de se obter dos experimentos, como a distribuição orientacional das moléculas de água na interface e sua dinâmica de difusão espacial. / Water films cover most of surfaces under ambient conditions. The study of these interfaces is crucial in biology and materials science. However, a complete understanding of water adsorption and its complex hydrogen bonding networks has not yet been achieved. Only recently we have techniques with the sensitivity and selectivity to study these surfaces to the last atomic layer. Sum-frequency generation (SFG) is a non-linear optical technique that provides the vibrational spectrum of molecules at interfaces, without contribution from the bulk. This technique was used to study the interfacial structure of neat (010) face of Gypsum (CaSO4 2H2O) single crystals and water adsorption on the (010) face at room temperature. The SFG spectra for the neat Gypsum face (010), in inert atmosphere, presented azimuthally anisotropy arrangement of the structural water molecules with the presence of OH groups bound to the surface and free OH groups pointing out of the surface. The arrangement of water molecules on the face (010) is anisotropic but different from that of the water molecules in the bulk crystal. Water adsorption was studied in equilibrium with water vapor at several values of relative humidity. The adsorbed water also exhibited an anisotropic arrangement, however, unlike the structural water, it presents a lower ordering and the free OH groups are strongly suppressed. The experimental results are analyzed together with ab initio molecular dynamics simulations performed by collaborators. The simulations presented good qualitative and quantitative agreement with the experimental results, elucidating the assignment of the experimental vibrational spectra and yielding information that would be difficult to get from the experiments, such as the orientational distribution of interfacial water molecules and their spatial diffusion dynamics.

Adsorção de água

Água confinada

Espectroscopia vibracional

Geração de soma de frequências

Gipsita

Confined water

Gypsum

Sum frequency generation

Vibrational Spectroscopy

Water adsorption