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Browsing by Subject "Kartoffel"

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    Managing trees on arable land
    (2020) Schulz, Vanessa Sarah; Graeff-Hönninger, Simone
    The cultivation of several plant species on the same area of land, at the same time, is called Agroforestry (AFS). In the less developed countries and the countries of the tropics and subtropics, AFS are the main form of land management. Reasons can be found in the low degree of mechanization and the low costs of labor. AFS used to be widespread in the industrial nations, too. Over the years, however, these traditional forms have been converted into highly efficient agricultural sites. Agricultural and forest production has been separated spatially. In Germany, this was mainly due to land consolidation, which resulted in large, uniform, and easy-to-farm fields. In recent years, however, this situation has been reconsidered. The positive environmental benefits and the aspect of biodiversity protection of agroforestry systems have been recognized. There are numerous ecological, economic, and social aspects, which make agroforestry attractive again. However, a competitive situation always arises when plants are cultivated together. In addition, there are multiple forms of AFS. Special attention must be paid to the planting of the woody, perennial component, as it remains on the field for several years. Against this background, this thesis deals with the possibilities of establishing the wood component in an AFS as a short rotation strip. Combinations of different tillage and weed management practices on willow growth and yield were tested. Furthermore, the influence of shade, which is listed as one of the three main influencing factors in AFS, is discussed. Agricultural crops behave differently, on shade casts by the woody component on the understory crop, depending on their need for light. To test this, maize was used as a shade-intolerant C4 plant, which reaches its light saturation close to maximum solar irradiance. In contrast, potato was tested as a more shade-tolerant C3 plant. Observations on growth, yield and quality should provide information on their suitability for cultivation under shady conditions in AFS. Various hypotheses were developed and examined for the purpose of testing. In the following, the most central research results will be briefly outlined. When establishing a short rotation coppice with willows, an adequate combination of soil tillage and weed management showed to be important for high yields, whereas the necessary weed management depends on the used soil tillage. Until today, there are no other recommendations for the establishment of a willow short-rotation coppice except ploughing in autumn, harrowing in spring and broad herbicide application. In the current discourse on biodiversity improvement and climate change, forms of reduced tillage (chisel plough + ley crop, no-till) with adapted herbicide-saving weed control (e.g. chemical treatment within the rows and mechanical treatment between the rows, or only mechanical weed control), were tested as alternatives that ensure successful SRC growth and, as a result, high yields while saving pesticides and fossil energy. When grown together, trees will shade the under-story agricultural crops. Some crops can deal better with this light reduction than others. Maize (Zea mays L.), as a plant with a high light saturation point, is already negatively influenced in its growth, the biomass, biogas, and methane yield, as well as the quality determining compounds (dry matter content, crude protein, crude ash) by low amounts of shade. While potatoes (Solanum tuberosum L.), known as shade-tolerant plants, can produce yields and qualities comparable to those of unshaded plants with lower levels of solar irradiance (caused by shading). It could be shown that it is possible to make a valuable contribution to biodiversity with AFS. By using adapted combinations of soil tillage and weed management systems, fossil fuels can be saved through reduced tillage. The use of chemical plant protection in the tree strips can be reduced by the sole application within the SRC strips or avoided altogether by mechanical weed control. In high-valuable timber systems there is usually no weed management necessary. Additionally, the trees strips offer a habitat and food basis for small vertebrates and some arthropods (hymenoptera, coleoptera, lepidoptera and diptera). The permanent planting of the strips reduces greenhouse gases and thus counteracts climate change. Influences of shade on crop yield and quality was only proven for plant-specific shade levels. In such AFS, the influence of shade usually only occurs in later tree ages (and crown thickness). Therefore, AFS are a valuable form of land management to reduce current environmental problems on a national and global scale, while adequate yields can be achieved at the same time.
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    Screening tools for late drought resistance in tropical potato
    (2023) Hölle, Julia; Asch, Folkard
    Potato (Solanum tuberosum L.) is a drought sensitive crop, and even short drought spells or infrequent irrigation during stolon formation, tuber initiation, or tuber bulking reduces tuber yields. A number of morphological traits have been described that potentially improve genotypic performance of potato under moisture deficit conditions. In breeding processes, a large set of genotypes are tested at the same time and because the genotypes differ in their phenology, various phenological stages occur simultaneously in the field. Consequently, during a drought spell different varieties will be subjected to soil moisture deficit at different phenological stages. We tested thirteen contrasting genotypes under field conditions in a desert in South Peru in four different irrigation treatments at two different soil types. The irrigation was withheld after 50, 65 and 80 days after planting until final harvest after 120 days. Sequential harvests, remote sensing and phenological evaluation was conducted in five to ten-days intervals. In literature, the belowground and aboveground development of potato has been described as closely and linearly related, meaning that in many studies belowground development is estimated according to aboveground development. The synchrony of the aboveground and belowground development is strongly influenced by both, water deficit and development stage at drought initiation. Under early drought, the aboveground development was accelerated and belowground development slowed. The opposite was found at later development stages. The earlier drought was initiated, the longer the tuber-filling phase, while the bulking phase was shortened. Water deficit also slowed down the aboveground development of flowering by a couple of days. In further drought experiments it is important to evaluated the belowground development separately, as we cannot conclude from the above to the belowground development stage. In conventional breeding experiments often only one final harvest is used to analyze the final tuber yield. This proceeding do not describe under which circumstances like stress intensity the tuber yield was achieved. Genotype evaluation in breeding experiments often relies only on visual evaluation of the aboveground biomass with no harvest of the plant. Besides the phenological stage at drought initiation the stress severity is another important aspect to determinate the drought stress response of potato genotypes. The stress severity depends on the water availability in term of soil water tension and the drought duration. In this study we developed a stress severity index (SSI) which combines all three important parameters, phenology, soil water tension and drought duration. With this SSI the selection processes should be improved and genotypes can be compared independently from environment, seasons and years. The SSI combines the yield response of potato to water deficit based on the soil tension the genotype was subjected to for the duration of the stress modified by the development stage of the genotype and drought duration. SSI allows for comparison of genotypic performance independent of year, location, season, soil type effects, and drought scenario. An SSI value of up to 1000 is able to differentiate between sensitive genotypes from more resistant genotypes. Beyond 1000, yields were generally reduced by more than 60% and a differentiation between genotypes was not possible anymore. SSI allows accumulating stress severity and thus, the higher the yield at a high SSI the stronger are the plants defense and adaptation mechanisms. Therefore, other indices that have looked into stay-green syndrome, rooting depth adaptations, leaf surface temperature, or canopy reflectance indices with only medium success, may benefit from including SSI in their indices to identify the underlying mechanisms of drought tolerance in potato. Remote sensing allows to evaluated many genotype simultaneously at field level. Proven indicators in drought tolerance screening are the normalized vegetation index (NDVI), the photochemical reflectance index (PRI) and thermography which describes the transpirational cooling of the leaves. Therefore, the last objective of this study was to validate the suitability of the SSI in remote-sensing stress diagnosis. The cluster analysis, including SSI, tuber yield reduction, NDVI, PRI and thermography identified three SSI groups with their corresponding physiological reactions under drought. The first group include SSI<1000 with fast decreasing NDVI, PRI and temperature deficit, in the second group matched SSI values from 1000 to 2000 with almost constant NDVI and temperature deficit and in the third group we found SSI beyond 2000 with corresponding small changes of NDVI, PRI and temperature deficit. The combination of these four parameters (tuber yield reduction, NDVI, PRI, thermography) explained 76 % of the variance which indicates this combination as valuable dataset analyzing drought tolerance in potato. Thus, combining these indicators with SSI and tuber yield reduction proved to be a first promising step for a new screening method for drought tolerance in a wider genotypic range. Whereas reflectance data can be recommended for assessing responses under mild to moderate stress severity, thermal imaging should rather be used to screen under mild or early drought stress.