Design And Synthesis Of Novel Soft Composites From Physical Gels And Nanomaterials

Pal, Asish

01 July 2008

The present thesis entitled “Design and Synthesis of Novel Soft Composites from Physical Gels and Nanomaterials” deals with soft materials derived from low molecular weight gels and nanomaterials. Chapter 1 gives a general introduction and overview of the low molecular weight gel (LMOG) which forms the basis of the work. It delves with the history of research in physical gel field, design of different types of gelator molecules, their interesting self-assembly patterns, potential applications of these gelator molecules as well as challenges to design new gelator molecules. It also encompasses the relatively recent area of two component gel system to conveniently bypass the cumbersome synthetic protocol. The aspect of liquid crystallinity in the gel phase is also discussed to throw light on the pattern of assembly and potential uses of these materials. Towards the end there is a comprehensive discussion on the smart nanocomposites derived from LMOGs and nanomaterials. The design, synthesis and numerous applications of inorganic-organic hybrid composites are discussed. Chapter 2A describes the synthesis and characterization of a variety of fatty acid amides of different naturally occurring L-amino acids whose molecular structures are shown in Chart 2A.1. Some of them were found to form gels with various hydrocarbons. The gelation properties of these compounds were studied by a number of physical methods including FT-IR spectroscopy, X-ray diffraction, scanning electron microscopy (SEM), differential scanning calorimetry, rheology and it was found that gelation was critically dependent on the fatty acid chain length and nature of the amino acid. Among them, L-alanine based gelators were found to be the most efficient and versatile as they self-assemble into a layered structure to form the gel network. Mechanisms for the assembly and formation of gels from these molecules are discussed. (Structural formula) Chart 2A.1. Molecular structures of various fatty acid amides of different amino acids. Chapter 2B describes efficient gelation of both aliphatic and aromatic hydrocarbon solvents by a fatty acid amide, n-lauroyl-L-alanine (Chapter 2B.1). In addition, this compound was found to gelate the binary solvent mixtures comprised of aromatic hydrocarbon e.g. toluene and aliphatic hydrocarbon e.g. n-heptane. SEM and AFM showed that the fiber thickness of the gel assembly increases progressively in the binary mixture of n-heptane and toluene with increasing percentage of toluene. The self- Chart 2B.1. Molecular structure of the gelator. assembly patterns of the gels in individual solvents, n-heptane and toluene are however, different. The toluene gel consists of predominantly one type of morphological species while n-heptane gel has more than one species leading to polymorphic nature of the gel. The n-heptane gel is thermally more stable than the toluene gel as evident from the measurement using differential scanning calorimetry. The thermal stability of the gels prepared in the binary mixture of n-heptane and toluene is dependent on the composition of solvent mixture. Rheology of the gels shows that they are shear-thinning material and show characteristic behavior of soft viscoelastic solids. For the gels prepared from binary solvent mixture of toluene and n-heptane, with incorporation of more toluene in the binary mixture, the gel becomes a more viscoelastic solid. The time sweep rheology experiment demonstrates that the gel made in n-heptane has faster gel formation kinetics than that prepared in toluene. Chapter 2C describes lyotropic mesophase formation by organogels of different fatty acid amides of L-alanine in aromatic solvents. The helical assembly, characteristic of the cholesteric mesophase was found to exhibit reflection bands in circular dichroism spectra. The reflection bands corresponded to the pitch of the helical arrangement of the gelator molecules in the aromatic solvent. Transmission Electron Microscopy (TEM) showed presence of twist in the gel fibres. Polarising optical microscopy of the organogel exhibited weak birefringence confirming lyotropic nature of the assembly. Chapter 3 deals with synthesis and characterization of a new class of molecules with molecular structures shown in Chart 3.1. Among a variety of amino acid based molecules only alanine and serine based molecules were found to form translucent gels in aliphatic hydrocarbons such as n-heptane. TEM showed presence of fiber like structures for alanine whereas serine based gelator produces unique network like structures. SEM of the dried gels exhibited presence of three dimensional fibrous networks to spongy globular cauliflower like structures depending on the molecular structure of the gelators. Rheological studies of the organogels showed that they behave like typical LMOG gels. The oscillatory rheological studies demonstrated that the L-serine based gelator, 5 formed more viscoelastic solid like gel than that of L-alanine based gelator, 1 in n-heptane. Chart 3.1. Molecular structures of different amino acid derivatives from 3,4,5-tri-dodecyloxybenzoic acid scaffold. Chapter 4A presents design and properties of new nanocomposites from LMOG and metal nanoparticles (Chart 4A.1). The profound influence of nanoparticle (NP) incorporation into physical gels was evident from various microscopic and bulk properties. The interaction of nanoparticles with the gelator assembly was found to depend critically on the capping agent coating the nanoparticles. TEM showed long range Chart 4A.1. Molecular structures of the gelator and various AuNPs synthesized. directional assembly of the certain AuNPs along the gel fibers. SEM of the dried gels and nanocomposites indicated that the morphological transformation in the composite microstructures depended profoundly on the capping agent of the nanoparticle. Differential Scanning Calorimetry showed that gel formation from sol postponed to lower temperature with incorporation of AuNPs having capping agents which were able to interact with the gel fibers. Rheological studies indicated that the gel-nanoparticle composites exhibit greater rigidity as compared to the naked gel only when the capping agents were able to interdigitate into the gelator assembly. Also, very low percentage of the AuNPs incorporation could switch the cholesteric mesophase of gel assembly, as evident from circular dichroism. We have been able to define a relationship between materials and molecular properties via manipulation of the molecular structures of NP capping agents. Chapter 4B discusses the design and preparation of novel organogel-carbon nanotube composites by incorporation of single-walled carbon nanotubes (SWNT) into physical gels formed by an L-alanine based Low Molecular Mass Organogelator (Chart 4B.1). The gelation process and the properties of the resulting nanocomposites were found to depend on the kind of SWNTs incorporated in the gels. With pristine SWNTs, only a limited amount could be dispersed in the organogels. Attempted incorporation of higher amounts of pristine SWNTs led to precipitation from the gel. To improve their solubility in the gel matrix, a variety of SWNTs functionalized with different aliphatic and aromatic chains were synthesized (Chart 4B.1). Scanning electron microscope images of the nanocomposites showed that the texture and organization of the gel aggregates were altered upon incorporation of SWNTs. The microstructures of nanocomposites were found to depend on the kind of SWNTs used. Incorporation of functionalized SWNTs into the organogels depressed the sol to gel transition temperature, with the n-hexadecyl chain functionalized SWNTs being more effective than the n-dodecyl chain functionalized counterpart. Rheological investigations of pristine SWNT containing gels indicated that the flow of nanocomposites became resistant to applied stress at a very low wt-% of SWNT incorporation. Again, more effective control of flow behavior was achieved with functionalized SWNTs possessing longer hydrocarbon chains. This happens presumably via effective interdigitation of the pendant chains with the fatty acid amides of L-alanine in the gel assembly. Also, the helical cholesteric mesophase formed by the toluene gel could be switched to a layer stacked assembly by doping functional SWNT. Remarkably, by using a near IR laser irradiation at 1064 nm for a short duration (1 min) at room temperature, it was possible to selectively induce a gel-to-sol phase transition of the nanocomposites, while prolonged irradiation (30 min) of the organogel under identical conditions did not cause gel melting. Chart 4B.1. Molecular structures of the gelator and different functionalized SWNT synthesized. Chapter 5A presents design of two component hydrogels and their potential utilization as a template for metal nanoparticle synthesis. Among a variety of acids and amines (Chart 5A.1) only stearic acid or eicosanoic acid when mixed with di- or oligomeric amines in specific molar ratios form stable gels in water. The formation of such hydrogels depends on the hydrophobicity of the fatty acid, and also on the type of amine used. The gelation properties of these two component systems were investigated using electron microscopy, FTIR, 1H NMR spectroscopy, differential scanning calorimetry (DSC) and both single crystal and cast film X-ray diffraction. FTIR spectral analysis suggests salt formation during gelation. 1H NMR of the gels indicates that the fatty acid chains are immobilized in the gel state and when the gel is melted, these chains regain their mobility. Analysis of DSC data indicates that increase in spacer length in the di-/oligomeric amine lowers the gel melting temperature. Two of these gelator salts developed into crystals and structural details of such systems could be secured by single-crystal X-ray diffraction analysis. The structural information of the salts thus obtained was compared with the XRD data of the self-supporting films of those gels. Such analyses provided pertinent structural insight on the supramolecular interactions that prevail within these gelator assemblies. From the crystal structure it is confirmed that the multilayered lamellar aggregates exist in the gel and it also showed that only one plane of symmetry is present in the gel state. Finally, the hydrogel was used as a medium for the synthesis of silver nanoparticles. The nanoparticles were found to position themselves on the fibers and produce a long ordered assembly of gel-nanoparticle composite (Figure 5A.1). Chart 5A.1. Structures and abbreviations of different acids and amines checked for gelation. Figure 5A.1. TEM images of gel-Ag-NP composite. (a) Ag-NP synthesized in hydrogel of SA-IBPA (1:3.5), (b) Magnified images of Ag-NP preferentially residing on gel fibers. Chapter 5B demonstrates the aptitude of supramolecular hydrogel formation using simple bile acids e.g. lithocholic acid (LCA) in aqueous solution containing di- or oligomeric amines (Chart 5B.1). By variation of the choice of the amines in such mixture the hydrogelation properties could be modulated. However, replacement of LCA by cholic acid or deoxycholic acid resulted in no hydrogelation. FT-IR studies show that the carboxylate and ammonium residues of the two components are primarily involved in salt formation. This promotes further assembly of the components reinforced by continuous Chart 5B.1. Structures and abbreviations of different bile acids and amines checked for gelation. hydrogen bonded network leading to gelation. Electron microscopy shows that the morphology of the gels of two component systems which also depends strongly on the amine part. Variation of amine component from the simple ethanediamine (EDA) to oligomeric amine with lithocholic acid changes the morphology of the assembly from long one dimensional nanotubes to three dimensional complex structures. Single crystal X-ray diffraction analysis with one of the amine-LCA complexes suggested the motif of fiber formation where the amines participate with the carboxylate and hydroxyl moiety through H-bonding and electrostatic forces. The rheological properties of this class of two component system provide clear evidence that this system is a shear-sensitive hydrogel and the flow behavior can be modulated varying the acid-amine ratio. From small angle neutron scattering study, it becomes clear that loose gel from LCA-EDA shows scattering oscillation due to the presence of non interacting nanotubules while for gels of LCA with oligomeric amine the individual fibers come together to form complex three dimensional structures of higher length scale.(For structural formula pl refer the pdf file)

Soft Composites

Gels

Nanomaterials

Low Molecular Weight Gel (LMOG)

Nanocomposites

Inorganic-Organic Hybrid Composites

Fatty Acid Amides - Synthesis

Organogel-Carbon Nanotube Composites

Hydrogels

Hydrocarbons - Gelation

Physical Gels

Nanoparticle Capping Agent

Natural Amino Acids

Materials Science

Synthesis, Physicochemical Studies And Gelation Properties Of Novel Bile Acid Derivatives

Nonappa, *

07 1900

Chapter 1. An Overview of Bile Acid Science This chapter deals with an overview of bile acid science (cholanology) compiling elevant literature review, covering bile acid chemistry, biosynthesis, bile salt evolution, physiology and medicinal values. Figure 1. (a) Digestive system; (b) enterohepatic circulation and (c) cholic acid Bile acids are the end products of cholesterol metabolism, secreted in the liver and stored in the gall bladder (Figure 1). They are normally conjugated with glycine (75%) or taurine (25%). Because of their facially amphiphilic nature, bile salts tend to form micellar aggregates in aqueous solution. They have remarkable ability to transform lamellar array of lipids into mixed micelles. All primary bile acids seem to have three features in common: (1) They are major products of cholesterol metabolism; (ii) they are secreted into the bile largely in a conjugated form and (iii) the conjugates are membrane impermeable, water soluble, amphiphilic molecules. Recent advances in molecular biology have greatly accelerated the knowledge relating to the significance of bile salts in a number of physiological functions. The new role of bile salts as pheromones and ligands for nuclear hormone receptors has been discussed. Chapter 2. Pythocholic Acid: A Major Constituent of Python’s Bile and 16α-Hydroxycholic Acid: A Minor Constituent of Avian’s Bile The first chemical synthesis of pythocholic acid (major constituent of python’s bile) and 16α-Hydroxycholic acid (a minor constituent of avian’s bile) were accomplished starting from cholic acid with overall yields of 5.0% and 5.5%, respectively. A biomimetic remote functionalization strategy was utilized as a key step to achieve the selective chlorination at C-17. Dehydrochlorination of 17-chlorosteroid resulted in the Δ16 olefin. Hydroboration-oxidation of the Δ16 olefin followed by the selective oxidation of the pentol under TEMPO mediated oxidation resulted in an ε-lactone. Hydrolysis of the lactone using 5% KOH in MeOH furnished the 16α-Hydroxycholic acid. On the other hand, selective oxidation of 7-OH of the lactone was achieved using N-bromosuccinimide in acetone/H2O to yield the 7-keto lactone. The ketolactone when subjected to the Huang-Minlon modification of the Wolf-Kishner reduction furnished pythocholic acid. Pythocholic acid showed unusual aggregation behavior and high cholesterol solubilization ability, compared to other trihydroxy bile acids. Chapter 3. 16-Epi-pythocholic acid: An Unnatural Analogue of Pythocholic Acid The synthesis of 16-epi-pythocholic acid, an unnatural analogue of pythocholic acid, was accomplished starting from cholic acid. Cholic acid was converted to Δ8-14) olefin using ZnCl2 in refluxing acetone. Methylation followed by isomerization in CHCl3 by passing dry. HCl at -78 oC resulted in the Δ14 olefin. Allylic oxidation using Na2Cr2O7.2H2O in the presence of N-hydroxysuccinimide in acetone furnished the enone. Selective reduction of the olefin using Pd/C-H2 resulted in 16-Epi-pythocholic acid the 16-keto steroid. NaBH4 reduction of this ketone in MeOH/THF (2:1 v/v) followed by hydrolysis produced the 16-OH bile acid. Analysis of spectral data confirmed that it is a 16β-epimer of pythocholic acid (3α,12α,16β-trihydroxy-5β-cholan-24-oic acid). Critical micellar concentration and cholesterol solubilization properties were studied. Chapter 4. Low Molecular Mass Organogelators Derived from Simple Esters of Cholic Acid This chapter begins with an introduction to low molecular mass organogelators and highlights their applications. Serendipitous gelation of a number of organic solvents by allyl cholate and the design of related simple esters of cholic acid are discussed. A series of simple and easily accessible esters of bile acids were prepared. Ethyl cholate and propyl cholate were found to immobilize a variety of organic solvents like benzene, toluene, xylene, mesitylene, 1,2-dichlorbenzene (DCB) and chlorobenzene (Figure 2). The morphology of the xerogels was well characterized using SEM, AFM and polarizing optical microscopy (POM) techniques, Which revealed the presence of highly entangled self-assembled 3D-fibrillar network (SAFINs). The fiber diameter was found to vary between 300-500 nm. Direct imaging of the collapse of this fibrillar network and direct observation of the evolution of nanofibers was achieved for the first time using variable temperature POM techniques. FT-IR studies, X-ray powder diffraction and variable temperature POM studies revealed the resemblance of SAFINs to the bulk solid. Formation of helical fibrillar network was observed in SEM images and the existence of chiral aggregates was confirmed by induced circular dichroism experiment using achiral Reichardt’s dye as the chromophore. Chapter 5. Ambidextrous Gelators Derived from Spacer Linked Bile Acid Derivatives Based on our observation of simple esters of cholic acid as organogelators a rational design of a series of spacer linked dimers and tripodal derivatives were carried out. Some of these molecules formed highly transparent gels in solvents like haloarenes, anisole, xylene and dibromoalkanes. These molecules also showed rapid gelation in DMF/H2O and DMSO/H2O mixtures in varying proportions of water and the co-solvent. These types of gelators are known as ambidextrous gelators. The xerogels were characterized using SEM, TEM and POM techniques and the presence of highly entangled 3D-fibrillar network (Figure 3) was observed. XRPD showed crystalline nature of bulk solid, whereas the xerogels were shown to lose their crystalline nature. (For figures and structural formula pl see the pdf file.)

Bile Acids

Organic Synthesis

Cholanology

Organogelators

Ambidextrous Gelators

Pythocholic Acid

Bile Acids - Synthesis

Bile Salts

Bile Acids - Gelation Properties

Cholic Acid

Xerogels

Bile Acid Derivatives

16-Epi-Pythocholic Acid

Organic Chemistry

Hydrolyzed Polyacrylamide- Polyethylenimine- Dextran Sulfate Polymer Gel System as a Water Shut-Off Agent in Unconventional Gas Reservoirs

Jayakumar, Swathika 1986-

02 October 2013

Technologies such as horizontal wells and multi-stage hydraulic fracturing have made ultra-low permeability shale and tight gas reservoirs productive but the industry is still on the learning curve when it comes to addressing various production issues. Some of the problems encountered while hydraulically fracturing these reservoirs are the absence of frac barriers, thinner shales and the increased presence of geological hazards. Induced vertical fractures sometimes extend to an underlying aquifer and become a conduit to the well. We have developed a low-concentration, low-viscosity and delayed-crosslink polymeric gel system as a water shutoff agent for hydraulically-fractured tight gas and shale reservoirs, where some fractures might connect to water rich zones. The system also is a significant improvement over traditional flowing gels for fracture water shutoff in conventional reservoirs because of these features. The gel uses high molecular weight hydrolyzed polyacrylamide (HPAM) at low polymer concentrations with a delayed organic crosslinker. This crosslinker is more environmentally benign and provides much longer gelation time and stronger final gels than comparable polymer loadings with chromium carboxylate crosslinkers at higher temperatures. The low viscosity system allows low-pressure extrusion of gelant into the narrow-aperture fractures present in unconventional gas reservoirs. The gelant can be pumped at low pressures due to lower polymer concentrations and delayed gelation point. This allows the potential to seal problem zones that are producing excess water even when the fractures conducting water have very narrow apertures. By impeding water production, the gel system developed here can effectively delay water loading thereby avoiding abandonment or installation of expensive equipment with increased operational costs, thus extending life and reserves of unconventional gas wells.

Shale gas excessive water production

High temperature water shut off

Delayed gelation

Polyethylenimine

HPAM gels

polymer gels

unconventional gas well water shut off

Polymer gels for water shut off

Water shut off

Structural Analysis and Electrochemical Properties of Bimetallic Palladium–Platinum Aerogels Prepared by a Two‐Step Gelation Process

Oezaslan, Mehtap, Herrmann, Anne-Kristin, Werheid, Matthias, Frenkel, Anatoly, Nachtegaal, Maarten, Dosche, Carsten, Laugier Bonnaud, Celine, Ceren Yilmaz, Hale, Kühn, Laura, Rhiel, Erhard, Gaponik, Nikolai, Eychmüller, Alexander, Schmidt, Thomas Justus

19 July 2018

Multi-metallic aerogels have emerged as a promising unsupported, high surface area-based metal material for different applications in heterogeneous catalysis and electrochemistry. The fabrication of these multi-metallic aerogels is based on a complex gelation process which is characterized by controlled aggregation of metallic nanoparticles to form a macroscopic network structure in aqueous solution. However, achieving structural homogeneity of the multi-metallic aerogels in terms of diameter of the nanochains and chemical composition at the nano- as well as at the macro-scale is still a great challenge. In this paper, we show the characterization of two Pd-Pt aerogels prepared by the two-step gelation method. The structural homogeneity and chemical distribution of both metals (Pd and Pt) inside the aerogels were analyzed using high-resolution (scanning) transmission microscopy (HR(S)TEM), energy-dispersive X-ray spectroscopy (EDX), extended X-ray absorption fine structure (EXAFS) spectroscopy, and cyclic voltammetry. Based on the microscopic and spectroscopic results, the Pd-Pt aerogels show the presence of Pd/Pt-rich domains inside the long-range framework. It is evident that the initial monometallic features dominate over alloying during the gelation process. Although the same synthetic approach for Pd-Pt aerogels with different atomic ratios was used, we observed that the sizes of these monometallic domains strongly varied between the Pd-rich and Pt-rich aerogels. For instance, the Pd-rich aerogels showed larger clusters with a size range from few nanometers up to several tens of nanometers, while the dimension of the clusters of the Pt-rich aerogels varies from the sub-nanometers to a few nanometers. The presence of the metal clusters strongly influenced the electrochemical robustness of these Pd-Pt aerogels. Electrochemical durability investigations revealed that the aerogels with a high content of Pd are less stable due to the gradual dissolution of the less noble metal in particular inside the Pd-rich domains. A better chemical and structural homogeneity might improve the life-time of the Pd-Pt aerogels under electrochemical conditions. In this work, we provide a better understanding about the structure and chemical distribution of the bimetallic aerogel framework prepared by the two step gelation process.

bimetallisches Aerogel

Pd-Pt

zweistufiges Gelierverfahren

chemische Homogenität

bimetallic aerogel

Pd-Pt

two-step gelation process

chemical homogeneity

ddc:540

rvk:VA 1120

Revestimento híbrido à base de TEOS/MPTS/MMA para proteção de aço-carbono e quinonas como agente anti-gelificante. / Hybrid coating based in TEOS/MPTS/MMA for carbon steel protection and quinones how anti-gelling agent.

Ernesto Bravo Anagua

29 April 2016

O problema de corrosão é frequente para ligas ferrosas, notadamente o aço carbono. Para evitar os danos causados pela corrosão, uma série de processos é utilizada como o uso de ligas mais resistentes, filmes de pré-tratamento e a aplicação posterior de tintas ou vernizes, aplicação de banhos eletrolíticos para eletrodeposição de metais e outros. Os últimos desenvolvimentos tecnológicos relacionados à nanotecnologia trazem alternativas que consiste na aplicação de uma camada muito fina baseada em silanos como pré-tratamento de aço carbono para posterior pintura a fim de aumentar a aderência desta ao substrato pintado. Este pré-tratamento surge como alternativa ao uso de materiais nocivos ao meio ambiente e à saúde, como são o processo de fosfatização e os compostos de cromo hexavalente aplicados como eventuais passivantes após a fosfatização. Questões ambientais, de segurança e de custos têm sido consideradas, atualmente, no que diz respeito à utilização desses processos. Por esta razão, aumentaram as pesquisas de outros métodos de proteção contra a corrosão para aço carbono. O uso de silanos tem demostrado ser uma alternativa promissora como pré-tratamento por serem promotores de aderência e conferirem melhor resistência contra a corrosão em diferentes aplicações. A aplicação de pré-tratamentos com filmes híbridos, isto é, com características de filmes orgânicos como flexibilidade e características de filmes inorgânicos ou cerâmicos como elevada dureza e resistência a altas temperaturas, tem sido estudada com relativo sucesso. O presente trabalho apresenta o uso de revestimentos híbridos tetraetilortosilicato/metacriloxipropiltrimetoxisilano/metacrilato de metila, TEOS/MPTS/MMA, como pré-tratamento para aço-carbono com a finalidade de retardar ou diminuir o processo da corrosão e o emprego de quinonas como agente anti-gelificante da solução precursora do híbrido, aumentando sua vida de prateleira. A avaliação da resistência à corrosão dos filmes obtidos foi feita por técnicas eletroquímicas como espectroscopia de impedância eletroquímica (EIE), medida da resistência de polarização linear (Rp) e levantamento de curvas de polarização. Também foi realizado o estudo com quinonas para retardar o envelhecimento das soluções de híbrido e aumentar o tempo de vida em prateleira. Alguns fatores estudados foram: tempo de polimerização, uso de quinonas como agente anti-gelificante (nesse estudo foi feito um projeto fatorial de experimentos) e tempo de vida de prateleira da solução de híbrido. As variáveis resposta, do projeto de experimentos, para avaliação do filme de híbrido obtido foram: medidas de EIE, de Rp, levantamento de curvas de polarização, espessura de camada e medida de viscosidade das soluções com o tempo de envelhecimento. Os resultados obtidos foram: o melhor tempo de polimerização foi de 30 minutos e foi para esse tempo de polimerização que se fez o estudo de uso das diferentes quinonas (hidroquinona e p-benzoquinona), tendo sido a p-benzoquinona o melhor anti-gelificante. Verificou-se que a espessura de camada do filme híbrido aumenta com o tempo de vida de prateleira da solução precursora do híbrido e com o tempo de permanência na solução do híbrido, o que leva o filme a funcionar como uma barreira mais eficiente contra a corrosão. A viscosidade foi determinada para cada uma das soluções de híbrido, tanto para aquelas que não foram usadas para a deposição de filmes e para aquelas que foram usadas para a deposição de filmes, com e sem quinonas. Observou-se que a viscosidade da solução de híbrido sem ser usada para deposição de filmes se manteve praticamente constante, mas a viscosidade da solução de híbrido que serviu para as deposições do filme híbrido no substrato aumentou com o tempo de prateleira, devido provavelmente à presença de íons metálicos do substrato liberados na solução de híbrido que podem catalisar as reações de polimerização dos silanos e do monômero MMA gerando moléculas de maior peso molecular. / The corrosion problem is common for ferrous alloys, especially carbon steel. To avoid corrosion damage a series of processes are used such as the use of resistant alloys, films of pre-treatment and the subsequent application of paints or varnishes, the application of electrolytic baths for the electrodeposition of metals and others. The latest technological developments related to nanotechnology bring an alternative process consisting in appling a very thin layer based on silanes as pretreatment for subsequent painting carbon steel in order to increase the adhesion of this to the painted substrate. This pretreatment is an alternative to the use of hazardous materials to the environment and health, as are the process of phosphating and hexavalent chromium compounds applied as eventual passivating substances after phosphating. Environmental, safety and costs concerns have been considered today in the use of these processes. Therefore, increased research for other methods of protection against corrosion of carbon steel has been developed. The use of polysilane films has been demonstrated to be a promising alternative as pre-treatment mainly because they have been employed as adhesion promoters what confers better corrosion resistance in different applications. This paper presents the use of hybrid coatings tetraethilorthosilicate /methacryloxypropyltrimethoxysilane/methylmethacrylate, TEOS/MPTS/MMA, as pre-treatment for carbon steel in order to delay or reduce the corrosion process and the use of quinones as anti-gelling agents of the hybrid precursor solution increasing its shelf life. The evaluation of the corrosion resistance of the films was made by electrochemical techniques such as electrochemical impedance spectroscopy (EIS), measurement of linear polarization resistance (Rp) and polarization curves. The use of quinones to slow the aging of hybrid solutions and increase their shelf-life time was also studied. A factorial design of experiments was performed for these purposes. The variables studied were: polymerization time, residence time of the substrate in the hybrid solution, use of quinones as anti-gelling agent and shelf life of the hybrid solution. The response variables for the design of experiments for evaluation of the hybrid films obtained were: EIS and Rp measurements, polarization curves, layer thickness and kinematic viscosity measurement of the solutions with aging time. The results obtained for best polymerization time was 30 minutes and for this polymerization time the study of use of different quinones (hydroquinone and p-benzoquinone) was made and p-benzoquinone was found to be the best anti-gelling agent. It was found that the thickness of the film layer increases with longer shelf life of the hybrid solution, which leads to more effective barrier films against corrosion. The viscosity was measured for each hybrid solution: for those that were not used for the deposition of films and for those that were used for the deposition of films, with or without quinones. It has been noted that the viscosity of the hybrid solution not used for the deposition of films was kept nearly constant but the viscosity increased with the shelf life for the hybrid solution that served for the hybrid film deposition on the metallic substrate, due to the influence of the metallic ions from the substrate released in the hybrid solution that can catalyze polimerization reactions of silanes and MMA monomer generating molecules of high molecular weight.

Aço carbono

Corrosão

Gelificação

Pré-tratamento

Quinonas

Revestimento híbrido

Sol-gel

Tempo de prateleira

TEOS/MPTS/MMA

Ageing time

Carbon steel

Corrosion

Gelation

Hybrid coating

Pretreatment

Quinones

Sol-gel

TEOS/MPTS/MMA

Influence de l'état protéique sur la dynamique de séparation de phase et de gélification dans un système ternaire aqueux à base de protéines de pois et d'alginate / Influence of protein state on the phase separation and gelation within an aqueous system made of pea proteins and alginate

Mession, Jean-Luc

14 September 2012

Deux systèmes aqueux à 20°C constitués de protéines globulaires de pois et d’alginate de sodium ont été considérés au cours de cette étude, dans des conditions de solvant fixées à pH 7,2 et 0,1 M NaCl. Dans un premier temps, le comportement de phase de globulines faiblement dénaturées (i) ou pré-agrégées thermiquement (ii) en mélange avec de l’alginate a été comparé à différentes échelles d’observation, en termes de diagrammes de phase et de microstructure analysée par microscopie confocale. Attribuée à un phénomène général d’incompatibilité thermodynamique, la séparation de phase a été décrite tout particulièrement sous des aspects morphologiques et cinétiques à l’échelle microscopique, selon la composition de départ en biopolymères et le mode de préparation des globulines. Par la suite, une gélification de chacun des deux systèmes a été opérée à froid, par libération de calcium ionique in situ à partir d’un sel de calcium de carbonate peu soluble au-dessus de pH 7, sous l’effet acidifiant d’une hydrolyse lente de la glucono-δ-lactone (GDL). L’intérêt d’un tel procédé reposait sur l’obtention de gels remplis à mixtes lorsque l’alginate seul ou l’alginate et la phase protéique pouvaient gélifier en présence de calcium. Des corrélations entre propriétés rhéologiques mesurées en régime dynamique (modules G’ et G’’) et données de microstructure ont été effectuées, par l’intermédiaire de l’analyse de texture d’image selon la méthode de cooccurrence. Chaque mélange témoignait d’une séparation de phase bloquée cinétiquement par sa gélification. Par rapport aux gels d’alginate seul ou gels remplis où l’alginate seul pouvait gélifier via le calcium, les gels mixtes témoignaient d’un effet de synergie remarquable d’un point de vue élasticité finale des gels. Dans le même temps, les globulines pré-agrégées ne montraient pas d’aptitude à la gélification selon le procédé appliqué ici. En outre, des effets ségrégatifs induisaient un enrichissement des protéines et du polyoside dans deux phases coexistantes, renforçant de ce fait des interactions entre biopolymères du même type. Les gels mixtes les plus élastiques présentaient une structure enchevêtrée avec un réseau protéique prédominant. Les observations en microscopie électronique à transmission effectuées par un marquage différentiel des deux biopolymères suggèreraient qu’il puisse se former localement des interactions attractives inter-biopolymères, probablement via le calcium, à l’interface des deux phases initialement immiscibles. Ce pontage consoliderait globalement la cohésion entre les deux réseaux protéique et polyosidique / Two aqueous systems at 20°C in 0.1 M NaCl and pH 7.2 containing globular pea proteins and sodium alginate were investigated in this study. First, phase behavior of (i) either low-denatured mixed globulins or (ii) their thermally pre-aggregated counterparts - alginate mixtures was compared using a multi-scale approach, by means of phase diagram and microstructure analysis by confocal microscopy. Thermodynamic incompatibility was the main driving force leading to phase separation within the mixtures, which presented according to their initial biopolymer composition both different morphological and time-evolution features of coexisting phases. Thereafter, a cold-set gelation for each system was performed, as the slow hydrolysis of glucono-δ-lactone (GDL) acidified the media and mediated the release in situ of calcium ions from calcium carbonate, practically insoluble at pH higher than 7. Such procedure would allow gelation via calcium of alginate only or both alginate and the protein phase, giving rise to filled and mixed gels, respectively. An attempt to correlate rheological measurements (G’, G’’ dynamic moduli) with microstructural data was carried out according to image texture analysis by the cooccurrence method. Phase separation was kinetically entrapped by gelation. Compared to single-alginate gels or native globulins-alginate filled gels where alginate was the only gelling agent via calcium, mixed gels reflected in fact great synergism effect regarding final gel elasticity. Meanwhile, pre-aggregated pea globulins could not form a gel with the gelation procedure of choice here. Besides, stronger segregative effects were evidenced by increasing initial biopolymer composition thus enhancing self-biopolymer interaction in their respective enriched-coexisting phases. The strongest mixed gels displayed entangled structure. According to a differential labelling of each incompatible biopolymer, observations with transmission electron microscopy suggested inter-biopolymer attractive interaction at the interface of coexisting phases, probably via calcium cations. Salt-bridging would reinforce cohesiveness between both protein and alginate networks

Protéines globuliares de pois

Alginate

Séparation de phase

Incompatibilité

Agrégation

Réseau

Gélification

Rhéologie

Microstructure

Globular pea proteins

Alginate

Phase separation

Incompatibility

Aggregation

Network

Gelation

Rheology

Microstructure

531

536

547

572

664

Etude physico-chimique d’organogels et d’aérogels de faible poids moléculaire dérivés d’acides aminés / Physico-chemical study of amino-acid-based low-molecular-weight organogels and aerogels

Allix, Florent

14 June 2011

Ce travail décrit la synthèse et les propriétés gélifiantes de nouveaux dérivés d’acides aminés de faible poids moléculaire dans des solvants organiques ainsi que l’élaboration d’aérogels correspondants par séchage au CO2 supercritique. Nous avons pu montrer, dans notre cas, que seuls les dérivés de la leucine et de la phénylalanine étaient nécessaires au phénomène de gélation. L’étude des paramètres des solvants a permis de montrer que les paramètres de Hansen h des solvants gélifiés s’inscrivaient dans un domaine étroit de valeurs faibles ; il inclut des solvants aromatiques et des solvants chlorés. L’usage de spectroscopies diverses (IR, RMN, dichroïsme circulaire et fluorescence) a permis de mettre en évidence les interactions responsables du phénomène de gélation. Les liaisons hydrogène permettent l’empilement unidimensionnel des molécules gélatrices, ces empilements s’associent ensuite grâce à des interactions de - stacking intercolonnaires. Des aérogels monolithiques ont pu être obtenus. Ils présentent des propriétés remarquables parmi lesquelles une conductivité thermique sous vide extrêmement faible / This work describes the synthesis and the gelation properties of new amino-acid-based low-molecular-weight derivatives in organic solvents as well as the development of the corresponding aerogels by supercritical CO2 drying. We have proved that in our case the presence of phenylalanine or leucine lateral chains were necessary for gelation. A solvent parameters study led us to define a favourable narrow h Hansen parameter domain for gelation including aromatic and chlorinated solvents. The use of several spectroscopy methods (IR, NMR, circular dihroism and fluorescence) allowed to settle the interactions accountable for gelation phenomenon. Hydrogen bonds enable the unidimensional stacking-up of gelator molecules; next, the stacking-up are associated through intercolumnar - stacking interactions. Monolithic aerogels were obtained. They display noteworthy properties among them an extremely low thermal conductivity under vacuum

Gélation

Organogel

Aérogel

Acide aminé

Paramètres de Hansen

Infrarouge

Résonance magnétique nucléaire

Dichroïsme circulaire

Fluorescence

CO2

Supercritique

Isolant thermique

Gelation

Organogel

Aerogel

Amino-acid

Hansen parameters

Infrared spectroscopy

Nuclear magnetic resonance

Circular dichroism

Fluorescence

Supercritical CO2

Thermal insulator

541.35

Zpracování, gelace a charakterizace atelokolagenu / Atelocollagen processing, gelation and characterization

Zubal, Lukáš

January 2018

Předkládaná disertační práce se zabývá charakterizací, zpracováním a gelací rozpustného kolagenu. Literární rešerše shrnuje postavení kolagenu na trhu s transplantáty, jeho aplikace a jednotlivé typy kolagenu. Detailně jsou rozebrány jednotlivé metody charakterizace rozpustného kolagenu a způsoby jeho gelace. Experimentální část je rozdělena na dvě podkapitoly. První podkapitola experimentální části se zabývá rozpouštěním a gelací rozpustného kolagenu v natlakované CO2 atmosféře. Proti jiným podobným metodám, metoda pracuje na poměrně nízkém tlaku (do 0.9MPa) a je bezpečná z pohledu denaturace kolagenu neboť funguje za nízké teploty blízké 0°C. Tímto způsobem mohou být průhledné gely, obsahující velmi tenká vlákna kolagenu, vytvořeny mnohem rychleji než za použití konvenčních metod. Rychlost gelace a transparentnost dává konceptu potenciál v oblasti oftalmologie a měla by přinést podstatné výhody pro injektovatelné produkty, vytváření mikro kuliček a 3D tisk. Druhá část popisuje unikátní charakterizaci rozpustného kolagenu v nativním stavu pomocí metody průtokové frakcionace s víceúhlovým rozptylem světla (AF4-MALS). Získaná molekulová hmotnost (při nejvyšší detekované koncentraci) odpovídá předpovězené hmotnosti a nativní i denaturovaný kolagen lze snadno rozeznat v konformačním grafu. Tato nová metoda poskytuje konzistentní a stabilní výsledky ve srovnání s ostatními zavedenými metodami. Metoda může být použita pro optimalizaci kvality výtěžků během výroby rozpustného kolagenu, nebo pro citlivou detekci denaturace během zpracování kolagenu.

Heterogeneous epoxy-amine networks from the dispersion of cross-linked polymer microparticles / Réseaux époxy-amine hétérogènes à partir de dispersions de microparticules polymères réticulées

Michon, Marie-Laure

14 February 2014

Lors de cette étude, il a été étudié l'influence de l'ajout de microparticules de polymère réticulé (CPM) dans des formulations d'époxy-amine, sur la cinétique, la morphologie et les propriétés thermo-mécaniques des réseaux finaux obtenus. Tout d'abord, un protocole simple, robuste et bien contrôlé a été développé afin d’ obtenir une large gamme de taille de CPM, de Tg et de fonctionnalité amine. Ce protocole de polymérisation par précipitation, basé sur les phénomènes de séparation de phases, a également été appliqué à différentes compositions chimiques et différents monomères époxy hydrosolubles, ceci montrant les grandes possibilités de cette méthode. Une bonne interface entre les CPMs et la matrice a été recherchée en synthétisant les CPMs en excès de groupes amines. La quantification de ces groupes amines réactifs sur les CPMS était d'un grand intérêt et a donc été étudiée en profondeur. Le titrage des amines de surface a été réalisé en mettant au point un nouveau protocole qui a permis la quantification des amines primaires et secondaires sur les CPMs. Il a ensuite été mis en évidence que, bien que ces microparticules réticulées ne soient pas poreuses, des fonctions amines sont disponibles au cœur des particules et peuvent réagir avec d'autres molécules qui sont capables de diffuser dans la CPM. Il a été montré que lorsque les CPM ont été dispersées dans des mélanges d'époxy- amine, la diffusion des monomères dans le cœur de la CPM s'est produite mais différemment selon le procédé de dispersion. En effet, en utilisant le tétrahydrofurane comme solvant pour aider à la dispersion, la diffusion de la DGEBA est amplifiée et modifie les propriétés thermo-mécaniques du réseau final en modifiant le rapport stœchiométrique de la matrice. Le même phénomène a été observé mais moins amplifié lorsque les microparticules sont uniquement dispersées mécaniquement. En dispersant les CPMs dans l'amine qui est l'agent réticulant, on observe l'absorption complète de l'amine au coeur des CPMs, conduisant ainsi à la désorption de celle-ci dans une deuxième étape, permettant de créer le réseau. Ainsi, un comportement très complexe des CPM a été mis en évidence en présence des monomères et/ou solvant : le gonflement et les phénomènes de diffusion qui dépendent d'un certain nombre de paramètres tels que la température, la densité de réticulation des CPM, les paramètres de solubilité, etc. L'intensité du phénomène de diffusion conduit à une variété de comportements lorsque les CPMs sont ajoutées dans une formulation d'époxy-amine tels que: (a) une légère diminution du temps de gélification et l'augmentation de la conversion, (b) la modification de la température de transition vitreuse de la matrice. / Throughout this work, the influence of the addition of cross-linked polymer microparticles (CPMs) in epoxy-amine formulations on the kinetics, morphology and thermo-mechanical properties of the final networks have been investigated. First, an easy, robust and well-controlled protocol was developed to obtain a large range of CPM size, Tg and amine functionality. This protocol based on reaction induced phase separation via precipitation polymerization was also applied to different chemistries and water soluble epoxy pre-polymers showing the large possibilities of this method. The capacity of obtaining a good compatibility between the CPMs and the matrix was ensure by synthesizing the CPMs in excess of amino groups. The study of the remaining reactive amino groups on the CPMS was of great interest and therefore deeply investigated. The titration of the surface amine was performed by developing a new protocol that enabled the quantification of primary and secondary amines on CPMs. It was then highlighted that even though these cross-linked microparticles were not porous, amino groups are available into the core and can react with other molecules that are able to diffuse into the CPM core. It was shown that when CPMs were dispersed into epoxy-amine blends, the diffusion of monomers into the CPM core occurred but differently depending on the dispersion process. Indeed, using tetrahydrofuran as solvent to help for the dispersion increased the diffusion of DGEBA into the CPM core and changed the thermo-mechanical properties of the final network by modifying the stoichiometric ratio of the matrix. Same phenomenon was observed but less amplified when CPMs were mechanically dispersed in DGEBA. Regarding the dispersion of CPMs in the amine cross-linker, IPD, its complete absorption could be observed into the CPMs, leading then to the desorption of IPD to create the network. Thus, a very complex behavior of CPMs was highlighted in presence of monomers or/and solvent: swelling and diffusion phenomena that are dependent on a number of parameters such as temperature, CPM cross-link density, solubility parameters, etc. The intensity of those phenomena leads to a variety of behaviors when CPMs are added into an epoxy-amine formulation: (a) slight decrease of gel times and increase of conversion, (b) modification of glass transition temperature of the matrix.

Polymère thermodurcissable

Réseau epoxy-Amine

Microparticule de polymère réticulé

Polymérisation par précipitation

Gélification

Vitrification

Séparation de phase

Amine en surface

Propriété thermomécanique

Thermosetting polymer

Amine epoxy network

Crosslinked polymer microparticle

Precipitation polymerization

Gelation

Vitrification

Phase separation

Surface amine

Characterization

Thermomechanical properties

620.192 072

Structural Analysis and Electrochemical Properties of Bimetallic Palladium–Platinum Aerogels Prepared by a Two‐Step Gelation Process

Oezaslan, Mehtap, Herrmann, Anne-Kristin, Werheid, Matthias, Frenkel, Anatoly, Nachtegaal, Maarten, Dosche, Carsten, Laugier Bonnaud, Celine, Ceren Yilmaz, Hale, Kühn, Laura, Rhiel, Erhard, Gaponik, Nikolai, Eychmüller, Alexander, Schmidt, Thomas Justus

19 July 2018

Multi-metallic aerogels have emerged as a promising unsupported, high surface area-based metal material for different applications in heterogeneous catalysis and electrochemistry. The fabrication of these multi-metallic aerogels is based on a complex gelation process which is characterized by controlled aggregation of metallic nanoparticles to form a macroscopic network structure in aqueous solution. However, achieving structural homogeneity of the multi-metallic aerogels in terms of diameter of the nanochains and chemical composition at the nano- as well as at the macro-scale is still a great challenge. In this paper, we show the characterization of two Pd-Pt aerogels prepared by the two-step gelation method. The structural homogeneity and chemical distribution of both metals (Pd and Pt) inside the aerogels were analyzed using high-resolution (scanning) transmission microscopy (HR(S)TEM), energy-dispersive X-ray spectroscopy (EDX), extended X-ray absorption fine structure (EXAFS) spectroscopy, and cyclic voltammetry. Based on the microscopic and spectroscopic results, the Pd-Pt aerogels show the presence of Pd/Pt-rich domains inside the long-range framework. It is evident that the initial monometallic features dominate over alloying during the gelation process. Although the same synthetic approach for Pd-Pt aerogels with different atomic ratios was used, we observed that the sizes of these monometallic domains strongly varied between the Pd-rich and Pt-rich aerogels. For instance, the Pd-rich aerogels showed larger clusters with a size range from few nanometers up to several tens of nanometers, while the dimension of the clusters of the Pt-rich aerogels varies from the sub-nanometers to a few nanometers. The presence of the metal clusters strongly influenced the electrochemical robustness of these Pd-Pt aerogels. Electrochemical durability investigations revealed that the aerogels with a high content of Pd are less stable due to the gradual dissolution of the less noble metal in particular inside the Pd-rich domains. A better chemical and structural homogeneity might improve the life-time of the Pd-Pt aerogels under electrochemical conditions. In this work, we provide a better understanding about the structure and chemical distribution of the bimetallic aerogel framework prepared by the two step gelation process.

info:eu-repo/classification/ddc/540

ddc:540