Publications by authors named "Jana B Schaubeder"
In the quest for greener and more efficient energy storage solutions, the exploration and utilization of renewable raw materials is essential. In this context, cellulose-derived separators play a central role in enhancing the performance of green energy storage devices. However, these often exhibit disadvantageous porosity and limited wet strength.
View Article and Find Full Text PDFDespite the potential of lignocellulose in manufacturing value-added chemicals and biofuels, its efficient biotechnological conversion by enzymatic hydrolysis still poses major challenges. The complex interplay between xylan, cellulose, and lignin in fibrous materials makes it difficult to assess underlying physico- and biochemical mechanisms. Here, we reduce the complexity of the system by creating matrices of cellulose, xylan, and lignin, which consists of a cellulose base layer and xylan/lignin domains.
View Article and Find Full Text PDFXylans' unique properties make it attractive for a variety of industries, including paper, food, and biochemical production. While for some applications the preservation of its natural structure is crucial, for others the degradation into monosaccharides is essential. For the complete breakdown, the use of several enzymes is required, due to its structural complexity.
View Article and Find Full Text PDFBackground: The abundance of glucuronoxylan (GX) in agricultural and forestry residual side streams positions it as a promising feedstock for microbial conversion into valuable compounds. By engineering strains of the widely employed cell factory Saccharomyces cerevisiae with the ability to directly hydrolyze and ferment GX polymers, we can avoid the need for harsh chemical pretreatments and costly enzymatic hydrolysis steps prior to fermentation. However, for an economically viable bioproduction process, the engineered strains must efficiently express and secrete enzymes that act in synergy to hydrolyze the targeted polymers.
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- Xylan contributes to the strength and integrity of plant cell walls, and its role during the pulping process significantly affects its functionality in papermaking.
- Enzymatic degradation of xylan leads to a weaker paper structure, whereas adding extra xylan enhances the paper's mechanical properties by improving fiber connections.
- The study emphasizes that maintaining intrinsic xylan during pulping is essential for achieving optimal paper strength, as extrinsic xylan alone cannot replicate these properties.
Activated carbon produced from biomass exhibits a high specific surface area due to the natural hierarchical porous structure of the precursor material. To reduce production costs of activated carbon, bio-waste materials receive more and more attention, which has led to a steep increase in the number of publications over the past decade. However, the characteristics of activated carbon are highly dependent on the properties of the precursor material used, making it difficult to draw assumptions about activation conditions for new precursor materials based on published work.
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- Enzymatic degradation of plant polysaccharides, like cellulose and hemicellulose, is complex and requires models that mimic natural systems to study it effectively.
- In this study, researchers used xylan-coated cellulose thin films to observe the activity of an enzyme called endo-1,4-β-xylanase, noting a correlation between enzyme concentration and the amount of xylan degraded.
- Results showed that both the enzyme concentration and incubation time significantly affected the degradation process, confirmed by atomic force microscopy, demonstrating a promising new model for studying biopolymer interactions at the nanoscale.