TY - JOUR A1 - Wehrhan, Marc A1 - Puppe, Daniel A1 - Kaczorek, Danuta A1 - Sommer, Michael T1 - Spatial patterns of aboveground phytogenic Si stocks in a grass-dominated catchment BT - results from UAS-based high-resolution remote sensing JF - Biogeosciences : BG N2 - Various studies have been performed to quantify silicon (Si) stocks in plant biomass and related Si fluxes in terrestrial biogeosystems. Most studies are deliberately designed on the plot scale to ensure low heterogeneity in soils and plant composition, hence similar environmental conditions. Due to the immanent spatial soil variability, the transferability of results to larger areas, such as catchments, is therefore limited. However, the emergence of new technical features and increasing knowledge on details in Si cycling lead to a more complex picture at landscape and catchment scales. Dynamic and static soil properties change along the soil continuum and might influence not only the species composition of natural vegetation but also its biomass distribution and related Si stocks. Maximum likelihood (ML) classification was applied to multispectral imagery captured by an unmanned aerial system (UAS) aiming at the identification of land cover classes (LCCs). Subsequently, the normalized difference vegetation index (NDVI) and ground-based measurements of biomass were used to quantify aboveground Si stocks in two Si-accumulating plants (Calamagrostis epige-jos and Phragmites australis) in a heterogeneous catchment and related corresponding spatial patterns of these stocks to soil properties. We found aboveground Si stocks of C. epige-jos and P. australis to be surprisingly high (maxima of Si stocks reach values up to 98 g Sim(-2)), i.e. comparable to or markedly exceeding reported values for the Si storage in aboveground vegetation of various terrestrial ecosystems. We further found spatial patterns of plant aboveground Si stocks to reflect spatial heterogeneities in soil properties. From our results, we concluded that (i) aboveground biomass of plants seems to be the main factor of corresponding phytogenic Si stock quantities, and (ii) a detection of biomass heterogeneities via UAS-based remote sensing represents a promising tool for the quantification of lifelike phytogenic Si pools at landscape scales. Y1 - 2021 U6 - https://doi.org/10.5194/bg-18-5163-2021 SN - 1726-4170 SN - 1726-4189 VL - 18 IS - 18 SP - 5163 EP - 5183 PB - Copernicus CY - Göttingen ER - TY - JOUR A1 - Schaller, Jörg A1 - Scherwietes, Eric A1 - Gerber, Lukas A1 - Vaidya, Shrijana A1 - Kaczorek, Danuta A1 - Pausch, Johanna A1 - Barkusky, Dietmar A1 - Sommer, Michael A1 - Hoffmann, Mathias T1 - Silica fertilization improved wheat performance and increased phosphorus concentrations during drought at the field scale JF - Scientific reports N2 - Drought and the availability of mineable phosphorus minerals used for fertilization are two of the important issues agriculture is facing in the future. High phosphorus availability in soils is necessary to maintain high agricultural yields. Drought is one of the major threats for terrestrial ecosystem performance and crop production in future. Among the measures proposed to cope with the upcoming challenges of intensifying drought stress and to decrease the need for phosphorus fertilizer application is the fertilization with silica (Si). Here we tested the importance of soil Si fertilization on wheat phosphorus concentration as well as wheat performance during drought at the field scale. Our data clearly showed a higher soil moisture for the Si fertilized plots. This higher soil moisture contributes to a better plant performance in terms of higher photosynthetic activity and later senescence as well as faster stomata responses ensuring higher productivity during drought periods. The plant phosphorus concentration was also higher in Si fertilized compared to control plots. Overall, Si fertilization or management of the soil Si pools seem to be a promising tool to maintain crop production under predicted longer and more serve droughts in the future and reduces phosphorus fertilizer requirements. Y1 - 2021 U6 - https://doi.org/10.1038/s41598-021-00464-7 SN - 2045-2322 VL - 11 IS - 1 PB - Macmillan Publishers Limited, part of Springer Nature CY - [London] ER - TY - JOUR A1 - Schaller, Jörg A1 - Puppe, Daniel A1 - Kaczorek, Danuta A1 - Ellerbrock, Ruth A1 - Sommer, Michael T1 - Silicon cycling in soils revisited JF - Plants : open access journal N2 - Silicon (Si) speciation and availability in soils is highly important for ecosystem functioning, because Si is a beneficial element for plant growth. Si chemistry is highly complex compared to other elements in soils, because Si reaction rates are relatively slow and dependent on Si species. Consequently, we review the occurrence of different Si species in soil solution and their changes by polymerization, depolymerization, and condensation in relation to important soil processes. We show that an argumentation based on thermodynamic endmembers of Si dependent processes, as currently done, is often difficult, because some reactions such as mineral crystallization require months to years (sometimes even centuries or millennia). Furthermore, we give an overview of Si reactions in soil solution and the predominance of certain solid compounds, which is a neglected but important parameter controlling the availability, reactivity, and function of Si in soils. We further discuss the drivers of soil Si cycling and how humans interfere with these processes. The soil Si cycle is of major importance for ecosystem functioning; therefore, a deeper understanding of drivers of Si cycling (e.g., predominant speciation), human disturbances and the implication for important soil properties (water storage, nutrient availability, and micro aggregate stability) is of fundamental relevance. KW - andosols KW - clay neoformation KW - crop yield KW - land use change KW - micro KW - aggregate stability KW - phytoliths KW - sediments KW - silicon cycling KW - silicon KW - extraction methods KW - silicon pore water speciation Y1 - 2021 U6 - https://doi.org/10.3390/plants10020295 SN - 2223-7747 VL - 10 IS - 2 PB - MDPI CY - Basel ER - TY - JOUR A1 - Puppe, Daniel A1 - Kaczorek, Danuta A1 - Schaller, Jörg A1 - Barkusky, Dietmar A1 - Sommer, Michael T1 - Crop straw recycling prevents anthropogenic desilication of agricultural soil-plant systems in the temperate zone BT - results from a long-term field experiment in NE Germany JF - Geoderma : an international journal of soil science N2 - Due to the fact that silicon (Si) increases the resistance of plants against diverse abiotic and biotic stresses, Si nowadays is categorized as beneficial substance for plants. However, humans directly influence Si cycling on a global scale. Intensified agriculture and corresponding harvest-related Si exports lead to Si losses in agricultural soils. This anthropogenic desilication might be a big challenge for modern agriculture. However, there is still only little knowledge about Si cycling in agricultural systems of the temperate zone, because most studies focus on rice and sugarcane production in (sub)tropical areas. Furthermore, many studies are performed for a short term only, and thus do not provide the opportunity to analyze slow changes in soil-plant systems (e.g., desilication) over long periods. We analyzed soil and plant samples from an ongoing long-term field experiment (established 1963) in the temperate zone (NE Germany) to evaluate the effects of different nitrogen-phosphoruspotassium (NPK) fertilization rates and crop straw recycling (i.e., straw incorporation) on anthropogenic desilication in the long term. Our results clearly show that crop straw recycling not only prevents anthropogenic desilication (about 43-60% of Si exports can be saved by crop straw recycling in the long term), but also replenishes plant available Si stocks of agricultural soil-plant systems. Furthermore, we found that a reduction of N fertilization rates of about 69% is possible without considerable biomass losses. This economy of the need for N fertilizers potentially can be combined with the benefits of crop straw recycling, i.e., enhancement of carbon sequestration via straw inputs and prevention of anthropogenic desilication of agricultural soil-plant systems. Thus crop straw recycling might have the potential to act as key management practice in sustainable, low fertilization agriculture in the temperate zone in the future. KW - Sustainable crop production KW - Straw incorporation KW - Phytoliths KW - Silicon exports KW - Plant available Si Y1 - 2021 U6 - https://doi.org/10.1016/j.geoderma.2021.115187 SN - 0016-7061 SN - 1872-6259 VL - 403 PB - Elsevier CY - Amsterdam ER -