Green barrier materials from cellulose nano fibers

Sharma, Sudhir

07 January 2016

Renewable, recyclable, and high performing barrier materials were made from cellulose nano fibers. Various strategies to enhance performance in dry, wet and humid conditions were proposed. These methods included thermal treatment to induce hornification, PAE resin based cross linking, and inclusion of high aspect ratio filler materials to form composites. Results indicated that hornification alone, even though effective in enhancing the barrier properties comes at the cost of severe degradation of mechanical properties. In the second case, where a cross linker was used, lower heating temperature limited the degradation of mechanical properties. Moreover, the new bonds included due to cross linking also modified the mechanical properties of the material and cause significant improvement. In the case of inclusion of filler materials, improvement of mechanical properties due to reinforcing effect was observed, and additionally the improvement in barrier properties was observed due to increased tortuosity of the materials. Furthermore, when the composites were made with cross linker, there was a significant improvement in barrier and mechanical properties as compared to the barrier material made from the pure cellulose nano fibers. In all cases the barrier materials were found to be resistant to degradation by water, as measured by water retention value, and surface contact angle. The resistance to water in the first case was as a result of severe hornification of the material. Whereas in the second and third case the cross linking and concomitant limited hornification played a significant role in water resistance. In addition to the three methods to improve barrier properties, the use of nano fibers made from cellulose II was also studied. Different stages of fibrillation of the starting cellulose pulps were studied and the fibers and films made from them were characterized in detail. Results from this study indicated that fibers made from cellulose II pulp are much harder to fibrillate as compared to cellulose I fibers. Moreover, due to fibril aggregation it is harder to form nano fibers from cellulose II. Even though from the perspective of better inter and intra fibril bonding cellulose II might be favorable over cellulose I, significant work in the formation of nano fibers from cellulose II is required before they can be used for making barrier materials.

Cellulose nano fibers

Barrier materials

Evaluation of Mechanical Properties of Provisional Fixed Partial Denture PMMA Material Containing Alumina Nanofibers

Hajjaj, Maher Saeed, 1980-

January 2012

Indiana University-Purdue University Indianapolis (IUPUI) / Provisional restorative treatment is an essential part of fixed prosthodontics. Incorporation of adequately constructed provisional restorations will enhance the success rate of definitive restorations. Repairing or replacing failed provisional restorations is a concern for both clinicians and patients. The objective of this investigation was to study the effects of alumina nanofibers reinforcement on the mechanical properties of commercially available provisional fixed partial denture PMMA material. The hypothesis was that the addition of alumina nanofibers to commercially available PMMA resin will significantly increase its flexural strength, fracture toughness, and microhardness. Alumina nanofibers at 0.0 wt %, 0.5 wt %, 1.0 wt %, and 2.5 wt % were added to commercially available provisional fixed partial material (Jet Tooth Shade). A quaternary ammonium acetate dispersant (CC-59, Goldschmidt, Janesville, WI) was added to the acrylic monomer at 0.0 wt %, 1.0 wt %, 2.0 wt % and 5.0 wt % of the nanofiber weight (12 test groups, 1 control). Samples from each group were evaluated for flexural strength, flexural modulus, fracture toughness, and microhardness. The samples were tested after storing in distilled water for 24 hours and 7 days at 37ºC. Two-way analysis of variance (ANOVA) was used to test the effects of storage time and combinations of alumina nanofiber level and quaternary ammonium acetate dispersant level on the flexural strength, fracture toughness, and microhardness of the provisional PMMA resin. Pair-wise comparisons between groups were performed using Tukey’s multiple comparisons procedure to control the overall significance level at 5 percent. Three fracture toughness samples/group were randomly selected for Energy Dispersive Spectrometry (EDS) to qualitatively evaluate the dispersion of the fibers. The data obtained from this study showed that control sample values were in the acceptance range compared with previous research. The experimental samples did not reinforce the provisional resin in the flexural strength, modulus, fracture toughness, or microhardness. There are several factors may attribute to these results, such as poor bonding at the filler/matrix interface. The more homogeneous the mixture of PMMA and fiber, the stronger the acrylic resin. In fact, the presence of poorly bonded fibers, to which little load is transferred, can be almost equivalent to voids. In addition, as seen with EDS images, alumina nanofibers had a tendency to agglomerate. The use of a magnetic stirrer was not effective in physically separating nanofibers agglomerates. Direct dispersion of alumina nanofibers in methyl methacrylate monomer and quaternary ammonium acetate dispersant was not effective in separating the nanofibers into nano-scaled single crystals. The presence of fiber agglomerates acts as a structural defect that detrimentally affects the mechanical properties. Further studies are needed to evaluate the effectiveness of fibers, dispersion techniques, and coupling agents to enhance the mechanical properties of the provisional PMMA resin.

Provisional restoration

PMMA

Polymethyl methacrylate

Alumina Nano fibers

Nano fibers

Energy Dispersive Spectrometry (EDS)

Polymethal Methacrylate -- chemistry

Aluminum Oxide -- chemistry

Nanofibers -- chemistry

Hardness

Compressive Strength

Pliability

Denture, Partial, Fixed

Flexible Transparent Electrically Conductive Polymer Films for Future Electronics

Zhao, Wei

07 April 2011

No description available.

Polymers

conductive fibers

electrically conductive films

flexible transparent conductive films

electrospinning

conductive films

nano fibers

flexible electronics

flexible conductive films

solution casting

transparency

conductivity

Development and Application of the Boundary Singularity Method to the Problems of Hydrodynamic and Viscous Interaction.

Mikhaylenko, Maxim A.

January 2015

No description available.

Mechanical Engineering

Boundary Singularity Method

stokes equations

microfluidics

allocation of singularities

matrix condition number

quasi-steady approach

viscous deformations

sub-micron and nano-fibers

FVM and BSM coupling