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Your search keyword '"Tammelin, Tekla"' showing total 7 results
Start Over Author "Tammelin, Tekla" Topic nanocellulose
7 results on '"Tammelin, Tekla"'

2. Ultra‐Low Grammage Nanocellulose‐Coated Woven Fabric with Improved Aerosol Particulate Filtration Performance.

Author

Li, Joanne, Tammelin, Tekla, Stone, Corinne, Dennis, Mike, and Lee, Koon‐Yang

Subjects
WATER vapor, AIR filters, TEXTILES, MILITARY personnel, AEROSOLS
Abstract

Developing advanced textiles and fabrics that offer protection against aerosolised chemical and biological hazards is of tremendous interest and is indispensable to the safety of the military personnel. Unfortunately, the extensive protection offered by protective clothing is often accompanied by a reduction in moisture vapour permeability, which increases physiological burden on the user (i.e., transport of sweat away from the body). This study shows that an enhancement in aerosol particulate filtration of a woven textile fabric can be achieved without impeding its water vapour transmission rate through the application of an ultra‐low grammage nanocellulose coating using a simple papermaking approach. Aerosol particulate filtration is realised in the nanocellulose coating through a size‐exclusion mechanism and the filtration efficiency doubled even at a nanocellulose grammage of 0.25 g m−2. As nanocellulose is hygroscopic, water vapour transmission rate remained unchanged compared to the uncoated woven fabric, regardless of the types of nanocellulose coating applied. The work also reports the mechanical robustness of the nanocellulose network fabricated, which is typically the concern in low‐grammage nanofibrous coating. [ABSTRACT FROM AUTHOR]

Published
2024
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3. Creaming layers of nanocellulose stabilized water-based polystyrene

Author

Gestranius, Marie, Kontturi, Katri S., Mikkelson, Atte, Virtanen, Tommi, Schirp, Claudia, Cranston, Emily D., Kontturi, Eero, Tammelin, Tekla, and Publica

Subjects
biocomposite, pickering emulsion, creaming layer, methyl cellulose, 3D printing, cellulose nanofibrils (CNF), additive manufacturing, nanocellulose
Abstract

Oil-in-water emulsions stabilized using cellulose nanofibrils (CNF) form extremely stable and high-volume creaming layers which do not coalesce over extended periods of time. The stability is a result of the synergistic action of Pickering stabilization and the formation of a CNF percolation network in the continuous phase. The use of methyl cellulose (MC) as a co-emulsifier together with CNF further increases the viscosity of the system and is known to affect the droplet size distribution of the formed emulsion. Here, we utilize these highly stable creaming layer systems for in situ polymerization of styrene with the aim to prepare an emulsion-based dope for additive manufacturing. We show that the approach exploiting the creaming layer enables the effortless water removal yielding a paste-like material consisting of polystyrene beads decorated with CNF and MC. Further, we report comprehensive characterization that reveals the properties and the performance of the creaming layer. Solid-state NMR measurements confirmed the successful polymerization taking place inside the nanocellulosic network, and size exclusion chromatography revealed average molecular weight (Mw) of polystyrene as approximately 700,000 Da. Moreover, the amount of the leftover monomer was found to be less than 1% as detected by gas chromatography. The dry solids content of the paste was ∼20% which is a significant increase compared to the solids content of the original CNF dispersion (1.7 wt%). The shrinkage of the CNF, MC and polystyrene structures upon drying-an often-faced challenge-was found to be acceptable for this composite containing highly hygroscopic biobased materials. At best, the two dimensional shrinkage was no more than ca. 20% which is significantly lower than the shrinkage of pure CNF being as high as 50%. The paste, which is a composite of biobased materials and a synthetic polymer, was demonstrated in direct-ink-writing to print small objects. With further optimization of the formulation, we find the emulsion templating approach as a promising route to prepare composite materials.

Published
2021

5. Cellulose nanopapers as tight aqueous ultra-filtration membranes.

Author

Mautner, Andreas, Lee, Koon-Yang, Tammelin, Tekla, Mathew, Aji P., Nedoma, Alisyn J., Li, Kang, and Bismarck, Alexander

Subjects
*CELLULOSE, *ULTRAFILTRATION, *ARTIFICIAL membranes, *ORGANIC solvents, *NANOFILTRATION
Abstract

Recently, we have demonstrated the use of wood-derived nanocellulose papers, herein termed nanopapers, for organic solvent nanofiltration applications. In this study, we extend the use of these nanopapers to tight ultrafiltration (UF) membranes. The feasibility of such nanopaper-based UF membranes intended for use in water purification is shown. Four types of nanocelluloses, namely bacterial cellulose, wood-derived nanocellulose, TEMPO-oxidized cellulose nanofibrils and cellulose nanocrystals, were used as raw materials for the production of these nanopaper-based membranes. The resulting nanopapers exhibit a transmembrane permeance in the range of commercially available tight UF membranes with molecular weight cut-offs ranging from 6 to 25 kDa, which depends on the type of nanocellulose used. These molecular weight cut-offs correspond to average pore sizes of a few nanometres. The rejection performance of the nanopapers is on the border of nanofiltration and UF. We demonstrate that the pore size of the nanopapers can be controlled by using different types of nanocellulose fibrils. [ABSTRACT FROM AUTHOR]

Published
2015
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6. Xylan as limiting factor in enzymatic hydrolysis of nanocellulose

Author

Penttilä, Paavo A., Várnai, Anikó, Pere, Jaakko, Tammelin, Tekla, Salmén, Lennart, Siika-aho, Matti, Viikari, Liisa, and Serimaa, Ritva

Subjects
*XYLANS, *LIMITING factors (Ecology), *ENZYMATIC analysis, *HYDROLYSIS, *CELLULOSE, *CRYSTALLINITY, *FOURIER transform infrared spectroscopy
Abstract

Abstract: The role of xylan as a limiting factor in the enzymatic hydrolysis of cellulose was studied by hydrolysing nanocellulose samples prepared by mechanical fibrillation of birch pulp with varying xylan content. Analyzing the nanocelluloses and their hydrolysis residues with dynamic FT-IR spectroscopy revealed that a certain fraction of xylan remained tightly attached to cellulose fibrils despite partial hydrolysis of xylan with xylanase prior to pulp fibrillation and that this fraction remained in the structure during the hydrolysis of nanocellulose with cellulase mixture as well. Thus, a loosely bound fraction of xylan was predicted to have been more likely removed by purified xylanase. The presence of loosely bound xylan seemed to limit the hydrolysis of crystalline cellulose, indicated by an increase in cellulose crystallinity and by preserved crystal width measured with wide-angle X-ray scattering. Removing loosely bound xylan led to a proportional hydrolysis of xylan and cellulose with the cellulase mixture. [Copyright &y& Elsevier]

Published
2013
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7. Pilot-scale modification of polyethersulfone membrane with a size and charge selective nanocellulose layer.

Author

Pöhler, Tiina, Mautner, Andreas, Aguilar-Sanchez, Andrea, Hansmann, Björn, Kunnari, Vesa, Grönroos, Antti, Rissanen, Ville, Siqueira, Gilberto, Mathew, Aji P., and Tammelin, Tekla

Subjects
*POLYETHERSULFONE, *MOLECULAR weights, *WATER purification, *SERUM albumin, *NANOSTRUCTURED materials, *NANOFILTRATION
Abstract

• Submicron nanocellulose layers generate highly hydrophilic anti-biofouling membrane surfaces. • Microfiltration membranes were altered to ultrafiltration and nanofiltration membranes. • Membrane roll-to-roll modifications were carried out using industrially relevant unit operations. • Nanocellulose layers displayed both size and charge selective separation mechanism with good mechanical integrity. The utilisation of plant-derived nanoscale cellulosic materials (cellulose nanofibrils, CNF) in tailoring water purification membranes is constantly gaining interest in the context of green-functionalised membrane solutions. However, most of the existing approaches based on renewable and biobased materials suffer from the lack of efficient and scalable processing strategies. Here, we introduce a roll-to-roll membrane modification approach based on thin submicron nanocellulose coatings (400–800 nm) to manufacture anti-biofouling membranes with size and charge dependent selectivity using unit operations compatible with existing industrial lines. We turned a commercial polymeric polyethersulfone (PES) microfiltration membrane into highly hydrophilic and tight membrane structure by applying thin and water-durable cellulose nanofibril layers using cast or spray coating methods. Nanocellulose coated membranes exhibited water permeance values of 80 – 100 LMH/MPa with the highest rejection levels of > 90% for Cytochrome C. Furthermore, the nanocellulose layers were able to withstand relatively high filtration pressure levels of 1 MPa, indicating that the selected procedures to improve mechanical integrity i.e. polyethylene imine-based anchoring and acid induced CNF cross-linking were successful. The coated membranes with the thinnest nanocellulose layer exhibited a molecular weight cut-off (MWCO) of 2 kDa for negatively charged polystyrene sulfonate and 14 kDa for neutral dextrane indicating charge selective behaviour. It can be concluded that our nanocellulose coated PES membranes represent nanofiltration membranes and lower boundary of ultrafiltration membranes with clear anti-biofouling performance directly evidenced via systematic bovine serum albumin (BSA) adsorption investigations. Our approach paves the way towards tunable and sustainable water treatment technologies simultaneously opening space for novel biobased solutions in membrane sector. [ABSTRACT FROM AUTHOR]

Published
2022
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