Your search keyword '"Wolter, Nick"' showing total 5 results

1. How Phosphorous Flame Retardant Additives Affect Benzoxazine‐Based Monomer and Polymer Properties.

Author

Haubold, Thorben S., Wolter, Nick, Sandinge, Anna, Blomqvist, Per, Mayer, Bernd, and Koschek, Katharina

Subjects

BENZOXAZINES, FIREPROOFING agents, HEAT release rates, MONOMERS, POLYMERS, RESORCINOL

Abstract

The phosphorous‐based flame retardant additives poly(m‐phenylene methylphosphonate) (PMP) and resorcinol bis(diphenyl phosphate) (RDP) are reacted with bisphenol F and aniline–based benzoxazine (BF‐a). DSC, rheological analysis, FT‐IR, and soxhlet extraction reveal the covalent incorporation of both FR additives—initiating phenols in PMP structure as well as free phenols generated via transesterification reaction in the case of RDP. In contrast to PMP, RDP elongates the processing window but decreases the thermo–mechanical properties. Both additives increase the resistance in reactions against small flames with solely a phosphorous loading of 0.3 wt%, resulting in a V‐0 rating and an improvement in the OI value by up to 2% for RDP and 4% for PMP. Both FRs reduce the heat release rate but increase the smoke production and the smoke toxicity in the case of RDP. [ABSTRACT FROM AUTHOR]

Published

2023

2. Effects of flame‐retardant additives on the manufacturing, mechanical, and fire properties of basalt fiber‐reinforced polybenzoxazine.

Author

Wolter, Nick, Carrillo Beber, Vinicius, Haubold, Thorben, Sandinge, Anna, Blomqvist, Per, Goethals, Frederik, Van Hove, Marc, Jubete, Elena, Mayer, Bernd, and Koschek, Katharina

Subjects

BENZOXAZINES, FIRE resistant polymers, BASALT, MEASUREMENT of viscosity, IGNITION temperature, SHEAR strength, ADDITIVES, POLYMERIC composites

Abstract

Basalt fiber‐reinforced polybenzoxazines (BFRP) were manufactured through vacuum infusion using resorcinol bis (diphenyl phosphate) and poly‐(m‐phenylene methylphosphonate) together with bisphenol‐F and aniline based benzoxazine. Different types and loadings of flame‐retardant additives showed to have catalysis or dilution effects in viscosity measurements. BFRPs show well‐penetrated fibers and near‐zero porosity. Additive addition did not influence tensile properties, while apparent interlaminar shear strength decreased indicating a lower adhesion between fiber and matrix. BFRP's heat and smoke release properties increased, though time to ignition increased and flammability behavior improved by decreasing delamination yielding oxygen indices in between 72 and 91%. [ABSTRACT FROM AUTHOR]

Published

2021

3. High-throughput cultivation and screening platform for unicellular phototrophs.

Author

Tillich, Ulrich M., Wolter, Nick, Schulze, Katja, Kramer, Dan, Brödel, Oliver, and Frohme, Marcus

Subjects

PHOTOSYNTHETIC bacteria -- Ultrastructure, BACTERIAL cultures, CYANOBACTERIA physiology, PHOTOSYNTHETIC reaction centers, MICROBIAL biotechnology, CYANOBACTERIA

Abstract

Background High-throughput cultivation and screening methods allow a parallel, miniaturized and cost efficient processing of many samples. These methods however, have not been generally established for phototrophic organisms such as microalgae or cyanobacteria. Results In this work we describe and test high-throughput methods with the model organism Synechocystis sp. PCC6803. The required technical automation for these processes was achieved with a Tecan Freedom Evo 200 pipetting robot. The cultivation was performed in 2.2 ml deepwell microtiter plates within a cultivation chamber outfitted with programmable shaking conditions, variable illumination, variable temperature, and an adjustable CO2 atmosphere. Each microtiter-well within the chamber functions as a separate cultivation vessel with reproducible conditions. The automated measurement of various parameters such as growth, full absorption spectrum, chlorophyll concentration, MALDI-TOF-MS, as well as a novel vitality measurement protocol, have already been established and can be monitored during cultivation. Measurement of growth parameters can be used as inputs for the system to allow for periodic automatic dilutions and therefore a semi-continuous cultivation of hundreds of cultures in parallel. The system also allows the automatic generation of mid and long term backups of cultures to repeat experiments or to retrieve strains of interest. Conclusions The presented platform allows for high-throughput cultivation and screening of Synechocystis sp. PCC6803. The platform should be usable for many phototrophic microorganisms as is, and be adaptable for even more. A variety of analyses are already established and the platform is easily expandable both in quality, i.e. with further parameters to screen for additional targets and in quantity, i.e. size or number of processed samples. [ABSTRACT FROM AUTHOR]

Published

2014

4. Screening and genetic characterization of thermo-tolerant Synechocystis sp. PCC6803 strains created by adaptive evolution.

Author

Tillich, Ulrich M., Wolter, Nick, Franke, Philipp, Dühring, Ulf, and Frohme, Marcus

Abstract

Background: Temperature tolerance is an important aspect for commercial scale outdoor cultivation of microalgae and cyanobacteria. While various genes are known to be related to Synechocystis sp. PCC6803's heat shock response, there is very limited published data concerning the specific genes involved in long term thermal tolerance. We have previously used random mutagenesis and adaptive evolution to generate a mixture of strains of Synechocystis sp. PCC6803 with significantly increased thermal tolerance. The genetic modifications leading to the phenotypes of the newly generated strains are the focus of this work. Results: We used a custom screening platform, based on 96-deepwell microplate culturing in an in house designed cultivation chamber integrated in a liquid handling robot for screening and selection; in addition we also used a more conventional system. The increased thermal tolerances of the isolated monoclonal strains were validated in larger bioreactors and their whole genomes sequenced. Comparison of the sequence information to the parental wild type identified various mutations responsible for the enhanced phenotypes. Among the affected genes identified are clpC, pnp, pyk2, sigF, nlpD, pyrR, pilJ and cya1. Conclusions: The applied methods (random mutagenesis, in vivo selection, screening, validation, whole genome sequencing) were successfully applied to identify various mutations, some of which are very unlikely to have been identified by other approaches. Several of the identified mutations are found in various strains and (due to their distribution) are likely to have occurred independently. This, coupled with the relatively low number of affected genes underscores the significance of these specific mutations to convey thermal tolerance in Synechocystis. [ABSTRACT FROM AUTHOR]

Published

2014

5. Carbon, Glass and Basalt Fiber Reinforced Polybenzoxazine: The Effects of Fiber Reinforcement on Mechanical, Fire, Smoke and Toxicity Properties.

Author

Wolter, Nick, Beber, Vinicius Carrillo, Sandinge, Anna, Blomqvist, Per, Goethals, Frederik, Van Hove, Marc, Jubete, Elena, Mayer, Bernd, and Koschek, Katharina

Subjects

GLASS fibers, FIRE resistant polymers, CARBON fibers, FIBERS, MECHANICAL properties of condensed matter, SMOKE

Abstract

Bisphenol F and aniline-based benzoxazine monomers were selected to fabricate basalt, glass and carbon fiber reinforced polybenzoxazine via vacuum infusion, respectively. The impacts of the type of fiber reinforcement on the resulting material properties of the fiber reinforced polymers (FRPs) were studied. FRPs exhibited a homogenous morphology with completely impregnated fibers and near-zero porosity. Carbon fiber reinforced polybenzoxazine showed the highest specific mechanical properties because of its low density and high modulus and strength. However, regarding the flammability, fire, smoke and toxicity properties, glass and basalt reinforced polybenzoxazine outperformed carbon fiber reinforced polybenzoxazine. This work offers a deeper understanding of how different types of fiber reinforcement affect polybenzoxazine-based FRPs and provides access to FRPs with inherently good fire, smoke and toxicity performance without the need for further flame retardant additives. [ABSTRACT FROM AUTHOR]

Published

2020