Cellulose fiber dissolution in sodium hydroxide solution at low temperature dissolution kinetics and solubility improvement /

Wang, Ying.

January 2008

Thesis (Ph.D)--Chemical Engineering, Georgia Institute of Technology, 2009. / Committee Chair: Deng, Yulin; Committee Member: Banerjee, Sujit; Committee Member: Frederick, James; Committee Member: Hsieh, Jeffery; Committee Member: Ragauskas, Arthur J.. Part of the SMARTech Electronic Thesis and Dissertation Collection.

The potential of zwitterionic bonding in paper /

Delgado, Ezequiel,

January 1994

Thesis (Ph. D.)--University of Washington, 1994. / Vita. Includes bibliographical references (leaves [123]-131).

Plasma processing of cellulose surfaces and their interactions with fluids

Balu, Balamurali.

January 2009

Thesis (Ph.D)--Chemical Engineering, Georgia Institute of Technology, 2010. / Committee Chair: Breedveld, Victor; Committee Chair: Hess, Dennis; Committee Member: Aidun, Cyrus; Committee Member: Deng, Yulin; Committee Member: Singh, Preet. Part of the SMARTech Electronic Thesis and Dissertation Collection.

Fracture Toughness Investigations of Micro and Nano Cellulose Fiber Reinforced Ultra High Performance Concrete

Peters, Sarah June

January 2009

No description available.

Cellulose fibers

Composite materials

Nanostructured materials

Model studies of cellulose fibers and films and their relation to paper strength

Fält, Susanna

January 2003

The objectives of this work were (i) to develop a new methodfor the preparation of thin cellulose model films, (ii) to usethese model films for swelling measurements and (iii) to relatethe swelling of fibers and films to the dry strength ofpaper. In the new film preparation method, NMMO(N-methylmorpholine-N-oxide) was used to dissolve cellulose andDMSO (dimethyl sulfoxide) was added to control the viscosity ofthe cellulose solution. A dilute solution of the cellulose wasspin-coated onto a silicon oxide wafer and the cellulose filmthus prepared was then precipitated in deionised water. Asaturated layer of glyoxalated-polyacrylamide was used toanchor the film onto the silicon oxide wafer. This proceduregave films with thicknesses in the range of 20-270 nm. Thefilms were cleaned in deionised water and were found by ESCAanalysis and contact angle measurements (θ&lt;20°)to be free from solvents. Solid state NMR measurements onfibers spun from NMMO also indicated that the model filmconsisted of about 50% crystalline material and that thecrystalline structure was of the cellulose II type.Determination of the molecular weight distribution of thecellulose surface material showed that the NMMO treatmentcaused only a minor breakdown of the cellulose chains and thatlow molecular mass oligomers of glucose were not created. It was further shown that atomic force microscopy (AFM)measurements could be used to determine the thicknessof thecellulose films, in both the dry and wet states. The thicknesswas determined as the height difference between the top surfaceand the underlying silica wafer measured at a position where anincision had been made in the cellulose film. The cellulosesolutions were also directly spin-coated onto the crystal usedin the Quartz crystal microbalance (QCM-D), pre-treated withthe same type of anchoring polymer. With this application,these model surfaces were shown to be suitable for swellingmeasurements with the QCM-D. The extent of swelling and theswelling kinetics in the presence of electrolytes, such asNaCl, CaCl2 and Na2SO4, and at different pH were measured inthis way. The films were found to be very stable during thesemeasurements and the results were comparable to the swellingresults obtained for the corresponding pulps. The swelling ofboth fibers and films followed the general behavior ofpolyelectrolyte gels in the presence of electrolytes and was inaccordance with the Donnan equilibrium theory. The films havebeen shown to differ from fibers with regard to the absence ofa covalent interior network. This influences the evaluation ofthe deswelling effects measured on the model films. Theswelling effect seen with different electrolytes has also beenconsidered in relation to the tensile strength of paperprepared from a kraftliner-pulp. In this study, it was foundthat there was no direct relationship between the swelling ofthe fibers, measured as WRV, and the strength of the paper inthe presence of different electrolytes at pH 5. KEYWORDS:absorption, carboxymethyl cellulose,cellulose, cellulose fibers, dissolving pulps, donnanequilibrium, electrolytes, film, ion exchange, ionization,kinetics, liner boards, microscopy, spinning, surfaces,swelling, tensile strength, water, water retention value. / <p>NR 20140805</p>

absorption

carboxymethyl cellulose

cellulose fibers

dissolving pulps

Polyelectrolyte multilayer films containing nanocrystalline cellulose

Cranston, Emily D.

January 2008

No description available.

Polyelectrolytes.

Thin films, Multilayered.

Nanocrystals.

Cellulose fibers.

Effect of Cellulose Fiber Addition on Autogenous Healing of Concrete and Their Use as a Bacteria-Carrier in Self-Healing Mortar

Singh, Harshbab

25 September 2019

Crack formation under tensile forces is a major weakness of concrete. Cracks make concrete vulnerable to the extreme environment due to the ingress of water and harmful compounds from the surrounding environment. Conventional methods of crack repairing are expensive and time consuming. It is estimated that in Europe, cost related to repair works is half of the annual construction budget and the US has average annual maintenance cost for existing bridges through the year is estimated to $5.2 billion. To overcome this problem, a self-healing concrete is produced based on the application of mineral producing alkaliphilic Bacillus Subtilis (strain 168) bacteria. Metabolic activities of these bacteria on calcium-based nutrients results in precipitation of calcium carbonate, which helps to repair concrete cracks. In bacteria based self-healing concrete, the bacteria are protected in the dense cementitious matrix by encapsulating them in “bacteria-carriers”. However, the presently available bacteria-carriers are not always suitable for concrete because of their complex manufacturing procedures or high cost. With the aim to develop a more suitable bacteria-carrier, in this study feasibility of cellulose fiber as a novel bacteria-carrier for self-healing mortar is investigated. Cellulose fibers compared to other bacteria-carriers can serve the dual purpose of arresting cracks and at the same time be a bacteria-carrier in large scale concrete construction. Two types of bacterial mortar by using cellulose fiber as a carrier was prepared. For one type, nutrients were added inside the mortar mix, while for the other, nutrients were added into the curing water. The two types of composites; control and cellulose fiber reinforced concrete (CeFRC) have also been investigated for autogenous healing of concrete. The crack healing efficiency of bacterial mortars was investigated using image analysis and ultrasonic pulse velocity (UPV) test and compared with unreinforced and control cellulose fiber mortars. Variation in compressive strength for all mixes compared to control mortar is also presented in this thesis. Research shows that self-sealing mortar using cellulose fiber as a bacteria-carrier result in maximum self-healing as compared to other mixes. This study also aims to evaluate the self-healing potential and water permeability of CeFRC. Compressive strength and flexural tests were also performed to evaluate the mechanical properties of the composites. Water permeability test was used to evaluate the coefficient of permeability and the self-healing performance was investigated by using UPV and a patented self-healing test. The results indicate that the water permeability coefficient decreased by 42% (+15% or -21%) whereas the healing ratio increased at a higher rate for the initial days of healing when cellulose fibers were added in the concrete. CeFRC also results in a 7.8% increase in flexural strength. / Graduate / 2020-09-13

Concrete

Self-healing

Bacteria-Carrier

Cellulose Fibers

UPV

A comparison of adsorptive potential energies for argon and nitrogen adsorption on the surface of cellulose fibers

Deitrich, Wayne H.

01 January 1970

No description available.

Physical chemistry

Cellulose fibers

Fibers

Nitrogen

Absorption

Adsorption

Argon

Adsorption kinetics in the polyethylenimine-cellulose fiber system

Kindler, W. A., Jr. (William Arthur)

01 January 1971

No description available.

Polymers

Polymerization

Adsorption

Polyethylenimine

Cellulose fibers

Mass transfer

The influence of aluminum salts on the adsorption of cationic polyelectrolyte by cellulosic fibers

Crow, Roger D.

01 1900

No description available.

Aluminum compounds

Cellulose fibers

Polyelectrolytes

Aluminum compounds

Adsorption