Effect of Ions and Admixtures on the Growth of Synthetic Calcium Silicate Hydrate (C-S-H)

Jirawan Siramanont
EPFL, 2018
Thèse EPFL

Résumé

This thesis investigates the effect of different parameters such as Fe (III), D-gluconate and heterogeneous particles on the nucleation and growth of synthetic C-S-H by using the dropwise precipitation method. Firstly, the effect of Fe (III) on the synthetic C-S-H system was investigated. This was achieved by controlling pH and also Fe (III) ion concentration. The experiments at pH higher than 11.0 of initial solutions containing Fe leads to the pre-precipitation of an amorphous Fe phase (ferrihydrite) which is then transformed to the more stable crystalline Fe phase of siliceous hydrogarnet. This condition is closely related to the phase formation pathway in real systems where the formation of ferrihydrite precludes the formation of the more thermodynamically stable iron containing siliceous hydrogarnet is also observed. To investigate the possible inclusion of Fe into the C-S-H structure, the experimental conditions were designed to avoid the pre-precipitation of ferrihydrite. This was achieved by controlling ionic speciation of the solution containing Fe with controlled pH (2.5). Magnetic resonance data strongly supported that the Fe (III) is incorporated into the C-S-H structure.

Secondly, this thesis investigates the effect of D-gluconate on the nucleation and growth of synthetic C-S-H. One effect of D-gluconate on synthetic C-S-H was a surface interaction which led to the formation of bi-pyramidal cage-like structures from the assembly of the precipitated C-S-H nanofoils. Characterization confirmed the adsorption of D-gluconate on the C-S-H surface but no changes in the underlying C-S-H structure could be discerned. From calorimetry data, D-gluconate not only interacts with newly precipitated C-S-H surfaces but also strongly on the dissolving solids in Portland cement e.g. alite, retarding hydration significantly. The complexation between calcium and D-gluconate in solution showed that increasing D-gluconate concentration gave more complexation with calcium and modified the kinetics of nucleation and growth. When collecting kinetics data to look at influences of D-gluconate on nucleation and growth mixed C-S-H morphologies nanoglobules, nanfoils and nanofibrils were observed. For a quantitative analysis by the population balance method recently developed in our lab such a mixed morphology cannot be analyzed. The experimental conditions for the collection of kinetics data for uniform morphology of precipitated synthetic C-S-H were found by controlling pH and D-gluconate concentrations. This new and unique kinetics data will in the near future be evaluated by using population balance modeling in order to discern the quantitative effect of nucleation and growth of precipitated synthetic C-S-H formation in the presence of D-gluconate.

Finally, to approach more real system conditions, heterogeneous particles (e.g. quartz and calcite) were introduced in the synthetic C-S-H system. Quartz and calcite were able to act as heterogeneous substrates for the nucleation and growth of precipitated synthetic C-S-H. The elemental maps confirmed uniformly distributed Ca, Si and O in nanofoils at the heterogeneous surfaces corresponding to the C-S-H composition. Without calcium ions in the silicate solution, calcite partially dissolved to give Ca2+ and CO32- ions which then formed C-S-H on its surface. Kinetics data shows different growth of C-S-H formation and will be evaluated in the future by using population balance modeling.

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https://infoscience.epfl.ch/record/258090?ln=fr

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Jirawan Siramanont
EPFL, 2018
Thèse EPFL

Résumé

Official source

https://infoscience.epfl.ch/record/258090?ln=fr

À propos de ce résultat

Concepts associés (24)

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Publications associées (32)

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Heterogeneous kinetics of some atmospherically relevant reactions

A low pressure reactor (Knudsen cell) coupled to molecular beam modulated mass spectrometry was used to study the heterogeneous kinetics of the following three systems: (1) NO2 on amorphous carbon, (2) H2O vapor on ice and (3) gaseous HCl on ice. The first system was investigated at ambient temperature while the two last ones were investigated at temperatures typical of the stratosphere, that is roughly between 160 and 220K. The solid phase samples correspond to model surfaces whose physicochemical properties come very close to the ones of atmospheric particulates. Firstly, we studied the interaction of gaseous NO2 with three different commercial samples of amorphous carbon having widely differing physicochemical properties. Using in situ laser-induced fluorescence, the only major product was unambiguously determined to be NO with the oxidation product of carbon apparently remaining on the surface. Probing the gas phase with mass spectrometry (MS), both pulsed valve dosing and steady state experiments were performed and revealed a complex reaction mechanism for both the uptake as well as product formation. The initial uptake coefficient γo for NO2 was (6.4±2.0)·10-2 and proved to be identical within experimental uncertainty for all three types of amorphous carbon. The initial NO2 uptake rate was independent of the mass of the carbon sample and scaled with its external geometrical surface. Applying a simple chemical kinetic model to both pulsed dosing and steady state experiments resulted in an effective surface for uptake on amorphous carbon ranging between a factor of 2.8 to 8.4 larger than the geometrical surface area, but inversely proportional to the measured BET surface area of the three types of amorphous carbon. This means that the amorphous carbon with the highest BET surface (FW2) had the lowest external surface for NO2 adsorption. The chemical kinetic model included competing processes between Langmuir-type adsorption and inhibition controlling the adsorption kinetics of NO2 and revealed that the NO generation rate differed greatly between the three carbon samples examined. All samples showed saturation effects of differing degree that were partially reversible through prolonged pumping at 10-4 Torr and/or heating. Virgin amorphous carbon samples did not take up H2O vapor at 20 mTorr, and no HONO and/or HNO3 was detected in simultaneous NO2/H2O exposure experiments. CO and CO2 were detected when a sample previously exposed to NO2 was heated by an incandescent lamp. Moreover, upon heating such a sample, a MS signal m/e 62 originating from NO3 and/or N2O5 was detected. In addition to the experiments conducted on the three commercial carbon samples, we carried out uptake experiments of NO2 on acetylene soot. Originating from the flame of an acetylene burner, this soot was freshly deposited on glass dishes before each experiment. The initial uptake coefficient γo for NO2 was measured to be (3.0±1.1)·10-2 is smaller by a factor of two compared to γo observed in the uptake on commercial samples whose mass was a factor of 10 higher. In addition to NO, a net formation of HONO (m/e 47) was observed. This HONO formation is strongly dependent on the instantaneous water desorption from the sample as well as on the NO2 partial pressure in the reactor. On the other hand, it is not enhanced by an external water flow which did not show any interaction with the carbon sample. Upon heating the sample using an incandescent lamp, significant amounts of water desorbed, suggesting that the water vapor had condensed into the micropores of the soot during combustion. No quantitative results are presented yet. However, as no correlation between HONO formation and NO partial pressure has been observed so far, we suggest a reaction mechanism that only involves NO2 and H2O but no NO: 2 NO2 (g) + H2O HONO + HNO3 In a second study, the kinetics of condensation and evaporation of water on ice was determined in the temperature range of 170 to 220K. The rate of evaporation Fev corresponds to the evaporation of 70±10 monolayers of H2O per second at 200K. The condensation rate constant kc has a negative activation energy of -3.l±1.5kcal/mol which is significantly larger than the one recently measured by Haynes et al. We report the first real time kinetic measurements of water condensation on ice at stratospherically relevant temperatures. At temperatures above 160K, pulsed dosing experiments show a dose dependence of the condensation rate coefficient. For example, the condensation rate coefficient increases by a factor of five with a 1000 fold increase of the H2O dose from 1·1015 to 1·1018 molecules per pulse at 180K. This pressure dependence of the condensation rate constant may be explained by an autocatalytic mechanism involving the competition of two condensation channels. These two channels feed two different surface species, one of which leads to autocatalytic condensation. This mechanism gives insight into the manner in which a gas phase molecule is stepwise incorporated into tetrahedrally coordinated bulk ice. In a third and ongoing study, the uptake kinetics of HCl on ice has been investigated by pulsed valve experiments in the temperature range of 180 to 210K and are discussed as a function of the state of the surface. In fact, some of the pulsed valve experiments present a relaxation to a steady state level. It is shown that this level originates from the evaporation of a liquid solution corresponding to a temperature specific HCl concentration. The threshold of the injected dose leading to this solution layer is estimated to be 8·1014 molecules. This threshold corresponding to a fraction of a monolayer may be explained by the formation of small domains along grain boundaries or other lattice imperfections. Within detection limit, no difference in keff has been observed for pulses on the solution or on a previously exposed sample without formation of the solution. In the case of pulses forming a solution layer, a fraction of 20±20% of the injected molecules remains permanently adsorbed on the surface. In the temperature range from 210 to 180K, the pulsed valve experiments yield values of keff roughly between 5 and 25s-1 and an activation energy of -1.6±0.7kcal/mol which are consistent with the values observed by Flueckiger in steady state experiments using the 15mm escape aperture (kuni varying from 12 to 23s-1 and an activation energy of -1.9±0.25 kcal/mol).

EPFL1996

Chargement

Since contrasts agents are used in magnetic resonance imaging (MRI), numerous efforts have been done to increase their relaxivity (parameter allowing to quantify contrast agent efficiency). Few years ago, the Merbach group developed the chelating agent DTTA (H4DTTA = diethylenetriaminetetraacetic acid = N,N'-[iminobis(ethane-2,1-diyl)]bis[N-(carboxymethyl)glycine]), which contains when complexed with gadolinium(III) in aqueous solution two inner-sphere coordination sites for water molecules. This chelate unit complexed with gadolinium(III) presents also a relatively fast inner-sphere water exchange rate which is favorable for the relaxivity. Three types of compounds have been studied in this thesis, all of them containing the DTTA chelate unit. The first is considered to be the monomer and allows studying the stability of the chelate unit. The second is a close derivative to the metallostar compound {Fe[Gd2bpy-DTTA2(H2O)4]3}4-, when the iron(II) central ion is replaced by a ruthenium(II) ion. The third is represented by the DTTA thiol derivative coated to gold nanoparticles. The first part of this thesis, chapter II, is thus the study of the physicochemical properties of the DTTA chelating moiety. For this purpose, the methylated derivative H4DTTA-Me (N,N'-[(methylimino)bis(ethane-2,1-diyl)]bis[N-(carboxymethyl)glycine]) was synthesized. Protonation and deuteration constants of the ligand were determined in an aqueous solution by potentimetry and 1H NMR pH titration and compared to various DTTA derivatives. Stability constants were measured for the chelates formed with Gd3+ (log KGdL = 18.60 ± 0.10) and Zn2+ (log ΚZnL = 17.69 ± 0.10). A novel approach of determining in a direct way the relative conditional stability constant of two paramagnetic complexes by 1H NMR relaxometry is presented and was used for the Gd3+ complexes [Gd(DTTA-Me)(H2O)2]- (L1) and [Gd(DTPA-BMA)(H2O)] (L2) [Κ*L1/ L2 (at pH 8.3, 25°C) = 6.4 ± 0.3]. The transmetalation reaction of the Gd3+ complex with Zn2+ in phosphate buffer solution (pH 7.0) was measured to be twice as fast for [Gd(DTTA-Me)(H2O)2]- in comparison to that for [Gd(DTPA-BMA)( H2O)]. This can be rationalized by the higher affinity of Zn2+ toward DTTA-Me4- if compared to DTPA-BMA3-. The formation of a ternary complex with L-lactate, which is common for DO3A-based heptadentate complexes, has not been observed for [Gd(DTTA-Me)( H2O)2]- as monitored by 1H NMR relaxometric titrations. From the results, it was concluded that the heptadentate DTTA-Me4- behaves similarly to the commercial octadentate DTPA-BMA3- with respect to stability. Considering recent suspicions against [Gd(DTPA-BMA)( H2O)] for being involved in Nephrogenic Systemic Fibrosis (NSF) disease, DTTA-type chelates will not be admitted as contrast agents in clinical MRI. However, their use in vitro and in animal studies is absolutely conceivable, mainly at high magnetic fields, where the increase of inner-sphere-coordination water actually seams to be the only promising way to increase the relaxivity markedly. The second part of this thesis, chapter III, presents the synthesis in aqueous solution and the magnetic and optical properties of the Ru(II)-based metallostars Na4{Ru[Ln2bpy-DTTA2(H2O)4]3} (Ln = Y, Gd, and Eu). The synthesis and the purification of the new, highly stable heptametallic entities have been optimized for the diamagnetic Y3+ complex and followed by 1H NMR. The europium(III) ruthenium-based metallostar {Ru[Eu2bpy-DTTA2(H2O)4]3}4- displays sensitized 5D0→7FJ luminescence upon excitation of the tris-(2,2'-bipyridyl)ruthenium(II) unit in both the ultraviolet around 293 nm, as well as in the visible around 450 nm (1MLCT state). NMRD profiles at two temperatures (25°C and 37°C) were measured on the {Ru[Gd2bpy-DTTA2(H2O)4]3}4-. NMRD profiles of the ruthenium-based {Ru[Gd2bpy-DTTA2(H2O)4]3}4- and iron-based {Fe[Gd2bpy-DTTA2(H2O)4]3}4- metallostars were fitted with SBM theory coupled to the model-free Lipary-Szabo method for internal motion as well as with the modified Florence approach. Comparison of both fitting methods shows that the Florence approach is able to fit NMRD profiles up to 100 MHz, fails however at higher frequencies because it does not account for internal motion. Overall, the results detailed point to the heptametallic self-assembled edifices being potential relaxivity and luminescence bimodal bioprobes. The third part of this thesis, chapter IV, is devoted to nano objects. We developed small, water-dispersible, stable nanoparticles covalently linked to Ln-DTTA derivative complexes (with Ln=Gd and Y) on the surface. Characterizations of these DTTA thiol capped gold nanoparticles (Gd-DtNP) using TEM images, dynamic light scattering technique and STEM with EDX analysis indicate 1.5-15.5 nm particle diameters, coated by Ln-Dt complexes on the surface. Molecular modeling shows a rough distance in the range of 1.3 nm between the lanthanide(III) ion and gold core surface and the structure that possess Ln-DtNP offers to lanthanide(III) a tightly bonding on the surface of particles. Accurate Au, Gd and Y concentrations have been determined by ICP-MS technique. Bulk magnetic susceptibility of samples with different gadolinium concentration has been established following the Evans method and no significant magnetic contribution can be attributed to the gold core. NMRD profiles of Gd-DtNP at 25°C show very high relaxivities and present broad relaxivity humps indicating very large systems with slow rotational motion. The modified Florence approach allows fitting well the experimental NMRD profil of Gd-DtNP, and the fitted electronic relaxation parameters are in good coherence with what was expected from the Ru-based metallostar values. Our Gd-DtNP systems are very rigid nano-object.

EPFL2008

Chargement

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NOVELTY - Determining a receptor-ligand interaction involves repeatedly contacting a cell comprising a receptor, with a ligand, of the receptor in which the ligand has a fluorescence labeling group and binds reversibly to the receptor under conditions in which the ligand associates with the receptor and then dissociates; and then repeatedly monitoring the fluorescence of the cell. USE - In a screening procedure for the identification and/or characterization of pharmaceutical drug candidate molecules and for determining a receptor-ligand interaction to allow sensitive measurements on single cells carried out in a microfluidic structure or on a chip (claimed) and can be used to characterize single or multiple cells by determining the presence of receptors or other proteins on the surface of the cells e.g. native cells, multiple cells like tissue sections, genetically modified cells or with cells immobilized on a solid surface, or in a matrix like a gel, or with cells in a liquid medium. ADVANTAGE - The method enables pharmacological investigations to be performed on single cells expressing the natural amount of receptor, which usually is very difficult due to photobleaching. The invention performs fluorescence binding assays, the reversible sequential binding assay that solves problems associated with previous measurements of ligand-receptor interactions by applying repetitively-completely reversible and specific fluorescently labeled ligands with fast association-dissociation kinetics. The new approach overcomes problems related to photobleaching so that cells expressing low amounts of receptors down to the single-molecule level can be investigated. The high sensitivity of the method allows the detection of little abundant proteins, thus enabling characterization of native cells. It can be applied even in the case of strong photobleaching opening the possibility to investigate single cells with low receptor concentrations comparable to native conditions in tissue cells. Furthermore, the influence of stimuli, such as ligands, can be rapidly and repetitively investigated using our reversible binding assay. A key advantage of the measurement approach is that pharmacological investigations can be performed on single cells expressing the natural amount of receptor, which usually is very difficult due to photobleaching. Using repetitive measurements, binding parameters can be extracted and investigations can be performed even when photobleaching becomes extremely strong as it is the case at lowest expression levels. Ultimately, single-molecule sensitivity can be achieved as illustrated on the nAChR. This opens the possibility to perform pharmacological investigations on tissue cells expressing minimal amounts of membrane receptors. By performing repetitive measurements, tenth of image sequences can be acquired to collect extensive statistics within a single experiment. High-throughput screening of potential drugs can be performed on a single cell with a rate only depending on the association-dissociation cycle time, consuming only minimal amount of testing components. One can expect that the use of ligands with faster kinetics could reduce this time down to 5 minutes. In addition, the use of more complex microstructures enables complete binding assays on a single cell or increasing statistics by parallel approaches using only some hundred nano liters of cell suspension. This way, screening more than 250 ligands per day using one single cell extracted from an animal tissue or obtained from a body fluid is a realistic goal.

2006

Chargement

Heterogeneous kinetics of some atmospherically relevant reactions

EPFL1996

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2006

EPFL2008