TEMPO-oxidized Nanocelluloses: Surface Modification and use as Additives in Cellulosic Nanocomposites

Johnson, Richard Kwesi

01 December 2010

The process of TEMPO-mediated oxidation has gained broad usage towards the preparation of highly charged, carboxyl-functionalized polysaccharides. TEMPO-oxidized nanocelluloses (TONc) of high surface charge and measuring 3 to 5 nm in width have been recently prepared from TEMPO-oxidized pulp. This study examines as-produced and surface-hydrophobized TONc as reinforcing additives in cellulosic polymer matrices. In the first part of the work, covalent (amidation) and non-covalent (ionic complexation) coupling were compared as treatment techniques for the hydrophobization of TONc surfaces with octadecylamine (ODA). Subsequently, TONc and its covalently coupled derivative were evaluated as nanofiber reinforcements in a cellulose acetate butyrate (CAB) matrix. The properties of the resulting nanocomposites were compared with those of similarly prepared ones reinforced with conventional microfibrillated cellulose (MFC). It was found that both ionic complexation and amidation resulted in complete conversion of carboxylate groups on TONc surfaces. As a result of surface modification, the net crystallinity of TONc was lowered by 15 to 25% but its thermal decomposition properties were not significantly altered. With respect to nanocomposite performance, the maximum TONc reinforcement of 5 vol % produced negligible changes to the optical transmittance behavior and a 22-fold increase in tensile storage modulus in the glass transition region of CAB. In contrast, hydrophobized TONc and MFC deteriorated the optical transmittance of CAB by ca 20% and increased its tensile storage modulus in the glass transition region by only 3.5 and 7 times respectively. These differences in nanocomposite properties were attributed to homogeneous dispersion of TONc compared to aggregation of both the hydrophobized derivative and the MFC reference in CAB matrix. A related study comparing TONc with MFC and cellulose nanocrystals (CNC) as reinforcements in hydroxypropylcellulose (HPC), showed TONc reinforcements as producing the most significant changes to HPC properties. The results of dynamic mechanical analysis and creep compliance measurements could be interpreted based on similar arguments as those made for the CAB-based nanocomposites. Overall, this work revealed that the use of TONc (without the need for surface hydrophobization) as additives in cellulosic polymer matrices leads to superior reinforcing capacity and preservation of matrix transparency compared to the use of conventional nanocelluloses. / Ph. D.

ionic complexation

amidation

octadecylamine

surface modification

nanocomposite

TEMPO-oxidized

nanocellulose

thermal decomposition

Design and fabrication of cellulose nanofibril (CNF) based microcapsules and their applications

Mubarak, Shuaib Ahmed

13 August 2024

Emulsions, comprising dispersed oil or water droplets stabilized by surfactants, are widely employed across industries. However, conventional surfactants raise environmental concerns, and emulsions may encounter stability challenges during storage. A promising alternative lies in Pickering emulsions, where particles adhere irreversibly at the water-oil interface, providing enhanced stability. Recent research explores the use of natural bio-based particles as interfacial stabilizers for creating Pickering emulsions, offering improved stability and environmental friendliness. This significant change towards particle-stabilized emulsions addresses sustainability and efficacy concerns. This dissertation investigates the application of cellulose nanofibrils (CNFs) in stabilizing Pickering emulsions for the development of functional microcapsules with diverse applications. A novel CNF aerogel with a hierarchical pore structure was developed using n-hexane-CNF oil-in-water (O/W) Pickering emulsions as templates. These hollow microcapsule-based CNF (HM-CNF) aerogels demonstrated high oil absorption capacities of 354 grams per gram for chloroform and 166 grams per gram for n-hexadecane, without requiring hydrophobic modifications, highlighting their potential as environmentally sustainable and high-performance oil absorbents. Further, the research explored the microencapsulation of n-hexadecane, an organic phase change material (PCM), within a hybrid shell of CNFs and chitin nanofibers (ChNFs). This method significantly improved the thermal stability of the encapsulated n-hexadecane, with maximum weight loss temperatures increasing from 184 degrees Celsius to 201 degrees Celsius with ChNF loading. The char yield also increased with ChNF content, indicating enhanced thermal degradation resistance. These emulsions demonstrated stability in various ionic solutions and elevated temperatures, showcasing their potential for applications such as thermal energy storage, cosmetics, food, and pharmaceuticals. Additionally, the dissertation examined stable water-in-oil (W/O) inverse Pickering emulsions using TEMPO-treated cellulose nanofibrils (TCNF). These emulsions, stabilized by TCNF-oleylamine complexes, exhibited droplet sizes ranging from 27 micrometers to 8 micrometers depending on TCNF concentration. They maintained stability under varying pH, ionic strength, and temperature conditions and demonstrated the encapsulation of water-soluble components like phytic acid, highlighting their versatility for diverse encapsulation applications. Overall, the research presents significant advancements in the utilization of CNF-stabilized Pickering emulsions, employing them as templates for fabricating aerogels and microcapsules. This approach enhances oil absorption, thermal stability, and encapsulation capabilities, offering eco-friendly solutions for diverse applications.