Enhanced performance and functionality of titanium dioxide papermaking pigments with controlled morphology and surface coating

Novel, tailored titanium dioxide pigments with controllable nanoscale morphological features were shown to significantly enhance the optical and strength properties of paper. The opacifying power of synthesized polycrystalline TiO2 particles in a cellulose matrix was found experimentally to be super...

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Main Author: Nelson, Kimberly Lynn
Published: Georgia Institute of Technology 2008
Subjects:
Online Access:http://hdl.handle.net/1853/24645
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spelling ndltd-GATECH-oai-smartech.gatech.edu-1853-246452013-01-07T20:27:48ZEnhanced performance and functionality of titanium dioxide papermaking pigments with controlled morphology and surface coatingNelson, Kimberly LynnHollow titanium dioxide nanoparticlesCellulose nanoparticlesHollow celluloseLight scatteringAggregatesLayer-by-layerEncapsulationTitanium dioxideCoatingsPigmentsPapermakingLight ScatteringNovel, tailored titanium dioxide pigments with controllable nanoscale morphological features were shown to significantly enhance the optical and strength properties of paper. The opacifying power of synthesized polycrystalline TiO2 particles in a cellulose matrix was found experimentally to be superior to that of a commercial rutile pigment, depending on the crystal structure of the synthesized particles. High aspect ratio polycrystalline rutile pigments composed of a linear linkage of several individual rutile crystals gave 6% more opacity than the commercial rutile pigment. Theoretical light scattering calculations using the T-Matrix Method showed the light scattering efficiency of linearly arranged polycrystalline rutile particles to depend on number and size of crystals composing the particle and confirmed the higher efficiency of the synthesized polycrystalline rutile pigments over commercial rutile. The opacifying power of hollow polycrystalline rutile particles was found experimentally to be superior to that of a commercial rutile pigment in a highly pressed bleached fiber matrix, depending on cavity size, while the opacifying power of silica-rutile titania core-shell particles was found comparable to commercial rutile at constant titania loading. The light scattering efficiency of titania core-shell particles was shown to be dependant on the light scattering efficiency of the core material. The overall particle shape and aspect ratio of titania core-shell and hollow nanoparticles were shown to be tunable by choosing an appropriate template and coating thickness in layer-by-layer or sol-gel templating synthesis. Inorganic-cellulose core-shell and hollow cellulose nanoparticles were prepared by self-encapsulation with regenerated cellulose via precipitation of cellulose in a polyacrylic acid hydrogel layer surrounding inorganic particle templates in 4-Methylmorpholine N-oxide (NMMO) monohydrate solution. This discrete encapsulation of inorganic pigments with a thin, uniform cellulose shell was found to increase the bondability improvement between the particles and a polysaccharide substrate. The crystallinity of several carbohydrate polymers was shown to significantly affect the bondability of encapsulated core-shell particles.Georgia Institute of Technology2008-09-17T19:27:19Z2008-09-17T19:27:19Z2007-07-06Dissertationhttp://hdl.handle.net/1853/24645
collection NDLTD
sources NDLTD
topic Hollow titanium dioxide nanoparticles
Cellulose nanoparticles
Hollow cellulose
Light scattering
Aggregates
Layer-by-layer
Encapsulation
Titanium dioxide
Coatings
Pigments
Papermaking
Light Scattering
spellingShingle Hollow titanium dioxide nanoparticles
Cellulose nanoparticles
Hollow cellulose
Light scattering
Aggregates
Layer-by-layer
Encapsulation
Titanium dioxide
Coatings
Pigments
Papermaking
Light Scattering
Nelson, Kimberly Lynn
Enhanced performance and functionality of titanium dioxide papermaking pigments with controlled morphology and surface coating
description Novel, tailored titanium dioxide pigments with controllable nanoscale morphological features were shown to significantly enhance the optical and strength properties of paper. The opacifying power of synthesized polycrystalline TiO2 particles in a cellulose matrix was found experimentally to be superior to that of a commercial rutile pigment, depending on the crystal structure of the synthesized particles. High aspect ratio polycrystalline rutile pigments composed of a linear linkage of several individual rutile crystals gave 6% more opacity than the commercial rutile pigment. Theoretical light scattering calculations using the T-Matrix Method showed the light scattering efficiency of linearly arranged polycrystalline rutile particles to depend on number and size of crystals composing the particle and confirmed the higher efficiency of the synthesized polycrystalline rutile pigments over commercial rutile. The opacifying power of hollow polycrystalline rutile particles was found experimentally to be superior to that of a commercial rutile pigment in a highly pressed bleached fiber matrix, depending on cavity size, while the opacifying power of silica-rutile titania core-shell particles was found comparable to commercial rutile at constant titania loading. The light scattering efficiency of titania core-shell particles was shown to be dependant on the light scattering efficiency of the core material. The overall particle shape and aspect ratio of titania core-shell and hollow nanoparticles were shown to be tunable by choosing an appropriate template and coating thickness in layer-by-layer or sol-gel templating synthesis. Inorganic-cellulose core-shell and hollow cellulose nanoparticles were prepared by self-encapsulation with regenerated cellulose via precipitation of cellulose in a polyacrylic acid hydrogel layer surrounding inorganic particle templates in 4-Methylmorpholine N-oxide (NMMO) monohydrate solution. This discrete encapsulation of inorganic pigments with a thin, uniform cellulose shell was found to increase the bondability improvement between the particles and a polysaccharide substrate. The crystallinity of several carbohydrate polymers was shown to significantly affect the bondability of encapsulated core-shell particles.
author Nelson, Kimberly Lynn
author_facet Nelson, Kimberly Lynn
author_sort Nelson, Kimberly Lynn
title Enhanced performance and functionality of titanium dioxide papermaking pigments with controlled morphology and surface coating
title_short Enhanced performance and functionality of titanium dioxide papermaking pigments with controlled morphology and surface coating
title_full Enhanced performance and functionality of titanium dioxide papermaking pigments with controlled morphology and surface coating
title_fullStr Enhanced performance and functionality of titanium dioxide papermaking pigments with controlled morphology and surface coating
title_full_unstemmed Enhanced performance and functionality of titanium dioxide papermaking pigments with controlled morphology and surface coating
title_sort enhanced performance and functionality of titanium dioxide papermaking pigments with controlled morphology and surface coating
publisher Georgia Institute of Technology
publishDate 2008
url http://hdl.handle.net/1853/24645
work_keys_str_mv AT nelsonkimberlylynn enhancedperformanceandfunctionalityoftitaniumdioxidepapermakingpigmentswithcontrolledmorphologyandsurfacecoating
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