Fakultät Agrarwissenschaften (Gesamt)

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    Energy security through decentralized energy system: Electricity self-sufficient village using agrivoltaics?
    (2025) Bauknecht, Martin
    With the Green Deal, the energy transition in the EU has gained momentum. Almost half of electricity consumption is now covered by renewable energies, with solar technology accounting for a significant share. However, the massive expansion of photovoltaics is increasingly being felt by every individual locally. The electrical grids are reaching their capacity limits. The number of redispatch measures is rising exponentially to keep the system running smoothly. This, in turn, is reflected on the electricity exchange in exorbitantly low exchange prices and, during windy and sunny hours, even in negative exchange prices. These trends raise the question of how energy security can be maintained and achieved in the future. In this context, a decentralized energy system is being modeled to create an electricity self-sufficient village using agrivoltaics. This has the advantage that the land can be used for dual purposes. The shared use of energy between citizens, commercials, municipalities and farmers creates a self-managed energy community. Farmers play a key role in this dual land use. This paper examines the central research question of what contribution an electricity self-sufficient village using agrivoltaics can make to energy security. This paper is based on a survey of 215 German farmers. The survey results show a trend that energy security can be increased through this modelled decentralized energy system. Various policy implications can be formulated for the realization of an electricity self-sufficient village using agrivoltaics. The first step is to achieve electricity self-sufficiency during the sunny months from March to October, until cross-seasonal storage media are available and ready for series production.
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    Genome-wide characterization of two-component system elements in barley enables the identification of grain-specific phosphorelay genes
    (2025) Hertig, Christian W.; Devunuri, Pravinya; Rutten, Twan; Hensel, Götz; Schippers, Jos H. M.; Müller, Bruno; Thiel, Johannes
    Background: The two-component system (TCS) serves as a common intracellular signal transduction pathway implicated in various processes of plant development and response to abiotic stress. With regard to the important cereal crop barley, only partial information about the occurrence of TCS signaling elements in the genome and putative functions is available. Results: In this study, we identified a total of 67 non-redundant TCS genes from all subgroups of the phosphorelay in the latest barley reference genome. Functional annotation and phylogenetic characterization was combined with a comprehensive gene expression analysis of the signaling components. Expression profiles hint at potential functions in vegetative and reproductive organs and tissue types as well as diverse stress responses. Apparently, a distinct subset of TCS genes revealed a stringent grain-specificity not being expressed elsewhere in the plant. By using laser capture microdissection (LCM)-based transcript analysis of barley grain tissues, we refined expression profiles of selected TCS genes and attributed them to individual cell types within the grain. Distinct TCS elements are exclusively expressed in the different maternal and filial cell types, particularly in the endosperm transfer cell (ETC) region. These genes are deemed to be selected in the domestication process of modern cultivars. Moreover, barley plants transformed with a synthetic sensor ( TCSn::GFP ) showed a high and specific activity in the ETC region of grains monitoring transcriptional output of the signaling system. Conclusions: The results provide comprehensive insights into the TCS gene family in the temperate cereal crop barley and indicate implications in various agronomic traits. The dataset is valuable for future research in different aspects of plant development and will be indispensable not only for barley, but also for other crops of the Poaceae.
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    Effectiveness of copper oxychloride coated with iron nanoparticles against earthworms
    (2024) Kumari, Tamanna; Phogat, Deepak; Jakhar, Navneet; Shukla, Vineeta
    This study examines the potential of iron nanoparticle-coated copper oxychloride in mitigating its toxic effects on earthworms, a key component of sustainable agriculture due to their role in enhancing soil quality and promoting plant growth. While earthworms and their coelomic fluid play a crucial role in enhancing soil health and promoting plant growth. Copper oxychloride, a commonly used fungicide, induces oxidative stress by disrupting antioxidant defense mechanisms in living systems. Through probit analysis, the median lethal concentration (LC50) of copper oxychloride was determined to be 2511.9 mg/kg. Artificial soil was treated with copper oxychloride at 60% and 80% of LC50, but the addition of iron nanoparticle-coated fungicide successfully reduced earthworm mortality to 0%. These findings offer promising insights into protecting non-target organisms from fungicide toxicity while maintaining agricultural productivity. The findings present a potential breakthrough in sustainable agriculture by demonstrating how nanotechnology can mitigate the harmful effects of fungicides on essential soil fauna. The use of iron nanoparticle-coated fungicides not only protects earthworms but also offers a path to maintaining ecological balance and enhancing crop productivity without compromising soil health.
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    Genebanks at risk: Hazard assessment and risk management of national and international genebanks
    (2023) Herbold, Theresa; Engels, Johannes M. M.
    Genebanks are crucial for safeguarding global crop diversity but are themselves exposed to several risks. However, a scientific basis for identifying, assessing, and managing risks is still lacking. Addressing these research gaps, this study provides risk analysis for three key risk groups: natural hazards, political risks, and financial risks, carried out on a sample of 80 important national and international genebanks, comprising at least 4.78 million accessions or roughly 65% of the reported total of ex situ conserved accessions worldwide. The assessment tool of Munich Re “Natural Hazards Edition” allowed a location-specific comparison of the natural hazard exposure. Results showed that genebanks in the Asia-Pacific region are most exposed to natural hazards, while institutions in African and some Asian countries are rather vulnerable to political risks. Financing is a major problem for national genebanks in developing countries, whereas the Global Crop Diversity Trust achieved considerable financial security for international genebanks. Large differences in the risk exposure of genebanks exist, making a location- and institution-specific risk assessment indispensable. Moreover, there is significant room for improvement with respect to quality and risk management at genebanks. Transferring risks of genebanks to third parties is underdeveloped and should be used more widely.