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1	The behavior of 4-O-methylglucoxylan in hot alkali. Ross, Richard John 01 January 1964 (has links) No description available. Physical chemistry Alkalis Polysaccharides Xylans American elm
2	A kinetic study of the rate of cleavage of the glycosidic bond of methyl-beta-glucopyranoside in an alkaline medium Brooks, Robert D. 01 January 1966 (has links) No description available. Bond cleavage Cellulose degradation Chemical degradation Alkalis
3	Reactions between Mullite based Refractories and Slag at Elevated Temperatures Olivas Ogaz, Mercedes Andrea January 2011 (has links) In the iron ore pelletizing, the sintering of the pellets takes place in a rotary kiln which is lined with refractory bricks. During the process, deposited materials such as iron ore slag, additives, binders and fly ash stick on the surface of the lining, and with time, by infiltration and diffusion, a corroded layer is formed. Some of the reactions occurred in that layer are promoted by the presence of alkalis. Refractory/deposited materials reactions and infiltration of deposited materials were studied at laboratory scale. In this study, techniques such as differential scanning calorimetry (DSC), x-ray diffractometry (XRD) and scanning electron microscopy (SEM) were used. Reaction temperatures, phase transformations and infiltration depth of deposited materials were determinated. Additions of alkalis into the materials involved were used to enhance the reactions between them. Using powder mixtures the results of DSC show that in addition of K2CO3 the reaction temperature range is 850-950°C showing formation of new phases around 850°C with kalsilite and around 950°C with leucite; in addition of the mixture Na2CO3 and K2CO3, there is a broader temperature interval of 600-925°C with formation of kalsilite at lower temperatures and nepheline at higher temperatures. In the characterization of the infiltration of deposited materials into the brick it was observed that nepheline was formed mainly in the corroded brick layer but K feldespathoids (leucite, kalsilite, kaliophilite) were formed beneath the corroded brick layer. / <p>Validerat; 20110705 (anonymous)</p> Technology refractories mullite slag alkalis Teknik
4	An analytical study of various pulps with reference to alkali binding and rosin sizing Downs, Martin Luther 01 January 1934 (has links) No description available. Paper sizing Gums Resins Sizing Rosin Papermaking Chemistry Alkalis
5	The distribution of sulfur throughout the wool structure and the effect of dilute alkali on that distribution. Shimp, Joseph Way 01 January 1944 (has links) No description available. Wool Chemical degradation Sulfur Fibers Mechanical properties Alkalis
6	A study on ozone modification of lignin in alkali-fiberized wood Lyse, Thomas E. (Thomas Edward) 01 January 1979 (has links) No description available. Ozone Chemical modification Lignins Alkalis Lignins Chemical degradation
7	Mécanismes d'action des fines et des granulats de verre sur la réaction alcali-silice et la réaction pouzzolanique Idir, Rachida January 2009 (has links) Recycling composite glass with different colours in order to be manufactured into new glass products is at present not economically viable. Therefore, the search for new issues other than stockpile areas or dumping sites could be a serious opportunity. To a certain extent, one of the possible solutions is to use the recycled glass in manufacturing cements and in the preparation of concrete mixtures. However, it is essential to manage the two main behaviours that the glass can have when used in cement-based materials: (1) the use of glass as coarse aggregates reveals harmful behaviour related to alkali-silica reaction; (2) on the other hand, it can result in useful behaviour related to pozzolanic reaction if used as fine particles. Furthermore, the significant alkali content should not be overlooked as their mass corresponds to about 13% of the total mass of the glass and as they may activate the alkali-silica reaction. An experimental programme was conducted to provide answers to the various questions raised about the use of glass in cement-based materials. The first part of this work was primarily devoted to the evaluation of the reactive potential of glass in mortars (alkali and pozzolanic reactions). At this stage, nine classes of glass particles ranging from 3[mu]m to 2.5 mm were considered. Then, fine glass particles were used in order to counteract the negative effect of some classes of coarse aggregates having revealed alkali-reactive behaviour. The second part of this work was performed to study the mechanisms that could explain the behaviours of fine and coarse particles in aqueous and concentrated environments. Different answers have been proposed to explain the observed behaviour in terms of grain sizes of glass. Mortars Alkalis Pouzzolanicity Alkali-silica reaction Alkali-aggregate reaction Alkali-reaction Aggregates Pozzolan Powder Glass
8	A study of the mechanism of alkali cellulose autoxidation Mattor, John A. 01 January 1963 (has links) No description available. Cellulose Oxidation Alkalis Reaction mechanisms Hydrogen peroxide Alkali cellulose Molecules Chemical bonds Reducing end groups
9	Alkalien in Chondren - offenes oder geschlossenes System? / Alkalis in Chondrules - open or closed system? Kropf, Andreas 13 March 2009 (has links) No description available. 550 Geowissenschaften Mathematics and Computer Science Chondren Chondenbildung solarer Nebel Alkalien Olivin chondrules chondrule formation solar nebular alkalis olivine TGL600 TGG900
10	Evolution physico-chimique des liants bas PH hydratés : influence de la température et mécanisme de rétention des alcalins / Physico-chemical evolution of low-pH cements : influence of the temperature and the retention mechanisme of alkalins Bach, Thi thuy ha 16 November 2010 (has links) Dans un site de stockage profond de déchets radioactifs, l’utilisation de matériaux à base de ciment Portland en association avec de l’argile pourrait se révéler inadaptée en raison de leur forte alcalinité. Une alternative serait de mettre en œuvre des ciments générant des solutions interstitielles de pH réduit (de l’ordre de 11 au lieu de 13,5 pour un CEM I). Les formulations étudiées dans cette thèse font appel à des ciments composés (également appelés « liant bas pH ») élaborés à partir de mélanges binaires (CEM I / fumée de silice) ou ternaires (CEM I / fumée de silice / cendres volantes ou laitier), avec de forts taux de substitution du CEM I (de 30% à 80%). Le travail réalisé répond à un double objectif : (i) étudier l’évolution chimique des liants bas pH à 50°C ou 80°C, températures qui pourraient être rencontrées dans certaines zones du stockage, et (ii) préciser les mécanismes à l’origine de la bonne rétention des alcalins par ces liants hydratés. (i) Le suivi sur une période d’un an de pâtes de liant bas pH montre que l’accroissement de la température de 20 à 80°C accélère l’hydratation des liants et favorise la consommation de la portlandite. L’allongement et la réticulation des chaînes de silicates des C-A-S-H est mise en évidence par RMN de l’27Al et du 29Si. L’ettringite observée dans les pâtes conservées à 20°C est par ailleurs déstabilisée. Les sulfates ainsi relâchés sont pour partie adsorbés sur les C-A-S-H et dissous dans la solution interstitielle. Le pH de cette dernière est réduit de 1,7 à 2,2 unités selon les formulations. En revanche, les fractions solubles d’alcalins n’évoluent pas de façon importante. Le liant ternaire T1 composé de 37,5% de CEM I, 32,5% de fumée de silice et 30% de cendres volantes est le seul des ciments étudiés à conduire à un pH de solution interstitielle inférieur à 11 aux trois températures considérées (20, 50 et 80°C - échéances 6 mois et 1 an). Son évolution à plus long terme a pu être simulée à l’aide de systèmes modèles reproduisant sa composition chimique à partir d’oxydes réactifs. A l’équilibre thermodynamique, l’assemblage minéralogique est constitué de C-A-S-H (rapports Ca/Si et Al/Si de 0,75 et 0,15 respectivement) ainsi que d’hydroxyde d’aluminium et de silice amorphes, et il impose un pH de 10,3 à 20°C. (ii) Ce sont les C-A-S-H qui jouent le rôle essentiel dans la rétention des alcalins. Le mécanisme mis en jeu est celui d’une compensation des charges négatives des C-A-S-H par interaction électrostatique. Il existe une sélectivité de sorption : le potassium est mieux retenu que le sodium. Celle-ci pourrait être attribuée en première approche à la différence de rayon solvaté entre ces ions. Une modélisation Monte Carlo des interactions électrostatiques entre des particules de C-S-H et un électrolyte contenant des ions sodium et potassium montre cependant que cette hypothèse ne suffit pas à elle seule à expliquer la sélectivité observée expérimentalement. / Because of their high alkalinity, Portland cement (OPC)-based materials may have deleterious effects in an underground waste repository. A solution would be to use low-alkalinity cements (also referred as low-pH cements) generating interstitial solutions with a reduced pH (11 instead of 13.5 for OPC), and thus showing an improved chemical compatibility with the repository environment. In this work, the investigated formulations were based on binary (OPC / silica fume) or ternary (OPC / silica fume / slag or fly ash) blends, with high substitution levels of CEM I (from 30% to 80%). This research project met two main objectives: (i) study the chemical evolution of low-pH cements at 50°C or 80°C, since such temperatures could be encoutered in certain zones of the waste repositories, and (ii) determine the mechanisms of alkali retention by hydrated low-pH cements. (i) Investigation of low-pH cement pastes with ongoing hydration over one year showed that increasing the temperature from 20°C to 80°C accelerated cement hydration and favoured the depletion of portlandite. A lengthening of the C-A-S-H silicate chains was also detected by 27Al and 29Si NMR analyses. Besides, ettringite precipitated at 20°C, but was destabilised at higher temperature. The released sulphates were partly adsorbed on the C-A-S-H and dissolved in the interstitial solution. The pH of this solution was reduced from 1.7 to 2.2 units depending on the formulations. The soluble fractions of alkalis did not significantly change with temperature. Among the five investigated blends, ternary binder T1 (37.5% CEM I, 32.5% silica fume, 30% fly ash) was the only one giving a pore solution pH lower than 11 at 20, 50 and 80°C (curing time of 6 months and 1 year). Its long-term evolution was simulated by model systems reproducing its chemical composition with reactive oxides. At equilibrium, the hydrate assemblage comprised C-A-S-H (Ca/Si and Al/Si ratios of 0.75 and 0.15 respectively), amorphous silica and aluminium hydroxide. It led to a pH of 10.3 at 20°C. (ii) C-A-S-H hydrates played a major role in the retention of alkalis. Sorption of potassium was higher than that of sodium and mainly resulted from electrostatic interactions with C-A-S-H. Monte Carlo modelling of these interactions showed that the difference of solvated radii between these ions could not explain by itself the sorption selectivity experimentally observed. Liants bas pH Fumée de silice Cendres volantes Laitier C-(A)-S-H Stockage géologique Alcalins Température Rétention Modélisation Monte Carlo Low pH binders Silica fume Fly ash Blastfurnace slag C-(A)-S-H Geological repository Alkalis Temperature Retention Monte Carlo modelling 620.19

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