Seeding Treatments to Enhance Seedling Performance of the Bulrushes Bolboschoenus Maritimus, Schoenoplectus Acutus and S. Americanus in Wetland Restorations

England, David M.

01 December 2019

A major goal in restoration is to reestablish native plant communities. There are several ways to reestablish species, but for large areas the most logistically feasible approach is to sow seed of desirable species. However, most wetland seeds are buoyant and are extremely difficult to establish in designated areas before floating away. In upland areas, tackifiers have been used to stabilize hill slopes from erosion and to keep seeds in place. The tackifier works as an adhesive that binds the seeds to the soil. However, the use of a tackifier has not been widely employed in wetland restorations, and prior to its broad implementation into wetland restoration practice, it is important to determine if tackifiers will hold up in wetland conditions. In greenhouse studies, we tested the effectiveness of different tackifier types and concentrations on Bolboschoenus maritimus seedling emergence, the influence of soil moisture and flooding on the duration of tackifier effectiveness, the effect of a mulch addition on tackifier effectiveness (Bolboschoenus maritimus, Schoenoplectus acutus and S. americanus), the effectiveness of pre-germination in enhancing Bolboschoenus maritimus seedling emergence using a tackifier, and the effectiveness of tackifier over time. We concluded that the use of a tackifier was effective at keeping seeds from washing away for at least 15 days, a mulch addition did not enhance tackifier effectiveness, and pre-germination did not benefit B. maritimus seedling emergence. The results from this study provide strong evidence that the use of a tackifier could be an effective solution to establish bulrush species in designated areas in wetland restorations.

wetland restoration

tackifier

seedling emergence

bulrush species

Microphase Separation Studies in Styrene-Diene Block Copolymer-based Hot-Melt Pressure- Sensitive Adhesives

Dixit, Ninad Yogesh

21 January 2015

This dissertation is aimed at understanding the microstructure evolution in styrene — diene block copolymer — based pressure-sensitive adhesive compositions in melt. The work also focuses on determining the microphase separation mechanism in adhesive melts containing various amounts of low molecular weight resin (tackifiers) blended with styrene — diene block copolymers. To understand the correlation between adhesive morphology and their dynamic mechanical behavior, small angle X-ray scattering (SAXS) and rheological analysis were performed on blends with different compositions. A modified Percus — Yevick model combined with Gaussian functions was used fit the liquid like disordered and bcc — ordered peaks of the SAXS intensity profiles. The morphological parameters derived from SAXS analysis corresponded to features such as the size and extent of ordering of the microphase separated polystyrene domains. The variation in these parameters with respect to temperature and adhesive composition correlated reasonably well with the trends observed in the shear modulus measured using rheological analysis. It was found that the ordering of polystyrene domains was influenced by the tackifier content in the adhesive blends. Polymer chain mobility was determined to be the dominant factor governing ordering kinetics, which depended on both the quench temperature and tackifier content in the blends. The addition of increasing amounts of tackifier eventually leads to a shift from a nucleation and growth type mechanism to a spinodal decomposition mechanism for phase separation and ordering. The compatibility of the tackifier with the polystyrene chains had a significant impact on the morphological transitions and microphase separation in adhesive blends. The blends containing a styrene — incompatible tackifier showed ordering over a broader range of temperatures compared to the blends containing a polystyrene — compatible tackifier. / Ph. D.

block copolymer

tackifier

SAXS

rheology

microphase separation

Effects of Tackification Agents on Room Temperature Epoxy Mechanical Properties

Murray, Garen B.

14 June 2022

When laying up dry composite materials and aligning the fibers in the appropriate directions it can be a challenge due to the dryness of the fiber and mold design. Several commercial products are available to help fix plies to molds keeping the proper fiber orientation depending upon mold geometry. Prepreg and wet layups do not have this problem due to the inherent inclusion of a matrix in their manufacturing, dry materials have no added epoxy at the time of layup and are therefore in need of assistance maintain position. The purpose of this research is to determine if Super 77™ or EPON™ 2002 increases or decreases mechanical properties of the neat resin and composite laminates; if the increase or decrease is dependent upon the type of epoxy, and if the amount of applied tackifier can be optimized towards a high or low application quantity to minimize any detrimental effects to mechanical properties. Each tackification agent was applied in high and low concentrations to eight composite panels, with two control panels. The EPON™ was applied manually and set with heat exposure while the Super 77™ was sprayed from an aerosol can. The Super 77™ plies were stacked and pressed by hand while the EPON™ plies were stacked and ironed together to create panels, which were then infused with one of two room temperature infusion epoxies, MVS 610 or INF 114. The panels were then cut to specimen size for testing. Neat resin specimens were cast in silicone molds with high and low concentrations of tackifiers and allowed to cure for 12 hours at room temp, then heated to 60° C for 8 Both Super 77™ and EPON™ 2002 reduced the SBS for both epoxies, but Super 77™ reduced the short beam shear more than EPON™ 2002. The modulus of the neat resin cast specimens with high concentration were between 0 to 20% lower than neat resin with no tackifier; the tensile strength was increased for those specimens with Super 77™ and lower for those with EPON™ 2002. Similarly, the Charpy test resulted in higher values for Super 77™ than for EPON™ 2002. The effects of Super 77™ and EPON™ 2002 are complex and varied depending on application concentration, resin, and tackifier type; but the addition of any tackifier reduces mechanical properties from non-tackified laminates.

Garen B. Murray

tackification

tackifier

binder

spray adhesive

resin infusion

vacuum infusion

out-of-autoclave

composite

laminate

epoxy casting

short beam shear

EPON™ 2002

3M™ Super 77™

Engineering