Your search keyword '"Christoph, Leuschner"' showing total 477 results

1. Effects of heat, elevated vapor pressure deficits and growing season length on growth trends of European beech

Author

Christoph Leuschner and Banzragch Bat-Enerel

Subjects

dendrochronology, climate-growth analysis, growing season length, growth decline, number of hot days, vapor pressure deficit, Forestry, SD1-669.5, Environmental sciences, GE1-350

Abstract

In recent decades, continued growth decline has been observed in various beech forest regions of Central and Western Europe, especially in the warmer lowlands, which is not necessarily linked to increased mortality. While earlier dendrochronological studies have shown that a deteriorating climatic water balance in the course of climate warming can drive negative growth trends, less is known about the effects of climatic extremes on tree growth, notably heat and rising atmospheric vapor pressure deficits (VPD). Through climate-growth analysis, we analyzed the influence of summer heat duration (frequency of hot days with Tmax > 30°C) and elevated VPD on the basal area increment (BAI) of dominant beech trees in 30 stands across a precipitation gradient in the northern German lowlands. Summer heat (especially in June) and elevated VPD are reducing BAI in a similar manner as does a deteriorated climatic water balance. While growing season length (GSL), derived from thermal thresholds of growth activity, has substantially increased since 1980, BAI has declined in the majority of stands, demonstrating a recent decoupling of tree productivity from GSL. We conclude that heat and elevated VPD most likely are important drivers of the recent beech growth decline in this region, while growing season length has lost its indicative value of beech productivity.

Published

2024

2. Winter and spring frost events delay leaf‐out, hamper growth and increase mortality in European beech seedlings, with weaker effects of subsequent frosts

Author

Lena Muffler, Robert Weigel, Ilka Beil, Christoph Leuschner, Jonas Schmeddes, and Juergen Kreyling

Subjects

acclimation, Fagus sylvatica, frost survival, frost tolerance, phenology, provenance trial, Ecology, QH540-549.5

Abstract

Abstract The persistence of plant populations depends crucially on successful regeneration. Yet, little is known about the effects of consecutive winter and spring frost events on the regeneration stage of trees from different seed sources, although this will partly determine the success of climate warming‐driven poleward range shifts. In a common garden experiment with European beech (Fagus sylvatica) seedlings from winter 2015/2016 to autumn 2017, we studied how simulated successive spring and winter frost events affect leaf‐out dates, growth performance, and survival rates of 1‐ to 2‐year‐old seedlings from provenances differing in climate at origin. We further investigated the combined effects of successive frost events. The first spring frost after germination led to a mortality rate up to 75%, resulting in reduced seedling numbers but better frost tolerance of the survivors, as reflected in a weaker impact of the following winter frost event in the survivors compared to the non‐acclimated control. Final plant height was most strongly reduced by the spring frost in the second year. The winter frost event delayed leaf‐out by up to 40 days, leading to severe growth impairment in 2017. Our results indicate partly successful frost acclimation and/or the selection of frost‐hardier individuals, because the negative growth effects of consecutive frost events did not add up after exposure to more than one event. Both mechanisms may help to increase the frost tolerance of beech offspring. Nevertheless, mortality after the first spring frost was high, and frost exposure generally caused growth reductions. Thus, achieving higher frost tolerance may not be sufficient for beech seedlings to overcome frost‐induced reductions in competitive strength caused by winter frost damage and delayed leaf enfolding.

Published

2024

3. Microtopography causes small‐scale variation in harvest and forage quality of high‐yielding silage grassland in northern Germany

Author

Angelika Mroncz, Johannes Isselstein, Martin Komainda, and Christoph Leuschner

Subjects

biomass map, dairy farming, drought, elevation differences, protein content, silage grassland, Agriculture (General), S1-972, Plant culture, SB1-1110

Abstract

Abstract Background Local sward dieback, especially in grasslands on peat soil, in response to the extreme 2018/2019 drought demonstrates climate vulnerability of intensive grasslands in northern Central Europe. Methods We explore the influence of microtopography, that is, the within‐field mosaic of depressions and elevated patches, on soil volumetric moisture content, standing biomass and biomass crude protein (CP) and fibre content in intensively managed grassland on peat soil in a moist year (2021) and a dry year (2022) for quantifying small‐scale spatial heterogeneity within a field. Results We found high within‐field variation in soil moisture, biomass and forage quality and a moisture dependence of productivity that was stronger in the dry year. CP ranged from 10% to 25% within a field, being lower in moist depressions than elevated patches in the wet (but not in the dry) summer. Conclusions The moister depressions help to limit the overall productivity decline in dry summers, whereas, in moist summers, the higher dry patches produce more protein‐rich forage than the depressions, where productivity is higher but quality is lower. We recommend adapting grassland management to this heterogeneity through spatially differentiated management regimes in order to better cope with an increasingly drier and more variable climate.

Published

2024

4. Inter-provenance variability and phenotypic plasticity of wood and leaf traits related to hydraulic safety and efficiency in seven European beech (Fagus sylvatica L.) provenances differing in yield

Author

Daniel Kurjak, Peter Petrík, Alena Sliacka Konôpková, Roman M. Link, Dušan Gömöry, Peter Hajek, Mirko Liesebach, Christoph Leuschner, and Bernhard Schuldt

Subjects

Assisted migration, Carbon isotope, Embolism resistance, Hydraulic conductivity, Provenance trial, Wood anatomy, Forestry, SD1-669.5

Abstract

Abstract Key message Seven European beech provenances differing largely in growth performance were grown at two common garden sites in Germany and Slovakia. The intra-specific variability of most traits was explained more by phenotypic plasticity than inter-provenance variability, and efficiency-related traits showed a higher phenotypic plasticity than safety-related traits. Context To maintain climate-resilient future forests, replicated common-garden experiments are suited for developing assisted migration strategies for key tree species. Aims We analysed the magnitude of inter-provenance variability and phenotypic plasticity for 12 functional traits of European beech (Fagus sylvatica L.) and analysed whether the climate at the place of origin left an imprint. Moreover, we asked whether growth is unrelated to xylem safety and to what extent the foliar, xylem and growth-related traits are coordinated. Methods Terminal branches were collected from 19-year-old and 22-year-old trees of seven European beech provenances planted at two common garden sites in Germany and Slovakia, respectively. Three hydraulic, three wood anatomical and four foliar traits were measured and related to two growth-related variables. Results At the two sites, the same pair of provenances showed the highest and lowest growth. Nevertheless, a high degree of phenotypic plasticity was observed, as all traits differed significantly between sites after accounting for provenance effects, with hydraulic safety-related traits showing the lowest and efficiency-related traits the highest plasticity. There was no evidence for inter-provenance variability in xylem embolism resistance (P 50) or the foliar carbon isotope signature (δ13C), a proxy for intrinsic water use efficiency (iWUE), and both were unrelated to growth. P 50 was positively correlated with the lumen-to-sapwood area ratio and vessel density. Conclusions Because of the lacking trade-off between embolism resistance and growth, highly productive provenances can be selected without reducing the drought tolerance of the branch xylem. However, as xylem safety is only one element of a trees’ drought response, it may be beneficial to select provenances with other more conservative drought adaptations such as smaller vessel lumen areas for increasing xylem safety and small supported total leaf areas for reduction of total transpiration.

Published

2024

5. Carbon density and sequestration in the temperate forests of northern Patagonia, Argentina

Author

Gabriel A. Loguercio, Alois Simon, Ariel Neri Winter, Horacio Ivancich, Ernesto J. Reiter, Marina Caselli, Facundo G. Heinzle, Christoph Leuschner, and Helge Walentowski

Subjects

carbon stocks, deadwood components, woody debris, topsoil organic carbon, secondary forest succession, Forestry, SD1-669.5, Environmental sciences, GE1-350

Abstract

IntroductionForests are a crucial part of the global carbon cycle and their proper management is of high relevance for mitigating climate change. There is an urgent need to compile for each region reference data on the carbon (C) stock density and C sequestration rate of its principal forest types to support evidence-based conservation and management decisions in terms of climate change mitigation and adaptation. In the Andean Mountains of northern Patagonia, extensive areas of temperate forest have developed after massive anthropogenic fires since the beginning of the last century.MethodsWe used a plot design along belt transects to determine reference values of carbon storage and annual C sequestration in total live (above- and belowground biomass) and deadwood mass, as well as in the soil organic layer and mineral soil (to 20 cm depth) in different forest types dominated by Nothofagus spp. and Austrocedrus chilensis.ResultsAverage total carbon stock densities and C sequestration rates range from a minimum of 187 Mg.ha−1 and 0.7 Mg.ha−1.year−1 in pure and mixed N. antarctica shrublands through pure and mixed A. chilensis forests taller than 7 m and pure N. pumilio forests to a maximum in pure N. dombeyi forests with 339 Mg.ha−1 and 2.2 Mg.ha−1.year−1, respectively. Deadwood C represents between 20 and 33% of total wood mass C and is related to the amount of live biomass, especially for the coarse woody debris component. The topsoil contains between 33 and 57% of the total estimated ecosystem carbon in the tall forests and more than 65% in the shrublands, equaling C stocks of around 100–130 Mg.ha−1 in the different forest types.ConclusionWe conclude that the northern Patagonian temperate forests actually store fairly high carbon stocks, which must be interpreted in relation to their natural post-fire development and relatively low management intensity. However, the current high stand densities of these forests may well affect their future carbon storage capacity in a warming climate, and they represent a growing threat of high-intensity fires with the risk of a further extension of burned areas in the future.

Published

2024

6. Climate-change-driven growth decline of European beech forests

Author

Edurne Martinez del Castillo, Christian S. Zang, Allan Buras, Andrew Hacket-Pain, Jan Esper, Roberto Serrano-Notivoli, Claudia Hartl, Robert Weigel, Stefan Klesse, Victor Resco de Dios, Tobias Scharnweber, Isabel Dorado-Liñán, Marieke van der Maaten-Theunissen, Ernst van der Maaten, Alistair Jump, Sjepan Mikac, Bat-Enerel Banzragch, Wolfgang Beck, Liam Cavin, Hugues Claessens, Vojtěch Čada, Katarina Čufar, Choimaa Dulamsuren, Jozica Gričar, Eustaquio Gil-Pelegrín, Pavel Janda, Marko Kazimirovic, Juergen Kreyling, Nicolas Latte, Christoph Leuschner, Luis Alberto Longares, Annette Menzel, Maks Merela, Renzo Motta, Lena Muffler, Paola Nola, Any Mary Petritan, Ion Catalin Petritan, Peter Prislan, Álvaro Rubio-Cuadrado, Miloš Rydval, Branko Stajić, Miroslav Svoboda, Elvin Toromani, Volodymyr Trotsiuk, Martin Wilmking, Tzvetan Zlatanov, and Martin de Luis

Subjects

Biology (General), QH301-705.5

Abstract

Tree ring data from a network of beech tree stands across Europe show evidence for a recent growth decline from 1986-2016 and project up to 50% growth reductions in some areas of Europe with future climate change.

Published

2022

7. Regeneration of Nothofagus dombeyi (Mirb.) Ørst. in little to moderately disturbed southern beech forests in the Andes of Patagonia (Argentina)

Author

Stefan Zerbe, Stefanie T. Storz, Georg Leitinger, Natalia Zoe Joelson, José Bava, Steffi Heinrichs, Christoph Leuschner, Gabriel Loguercio, Alois Simon, María F. Urretavizcaya, and Helge Walentowski

Subjects

Agroforestry, Disturbance, Fire management, Forest grazing, Forest management, Plant traits, Ecology, QH540-549.5

Abstract

Natural forests and stands subjected to little to moderate human impact are continuously declining worldwide and with these, their biodiversity and ecosystem services. Many Nothofagus forests in the south of the South American continent are in a pristine state or only moderately impacted by humans. Forest grazing by livestock, in the past and still today often practiced in a non-sustainable way is, however, increasingly under discussion to meet current environmental and socio-economic challenges. Accordingly, we investigate the regeneration of Nothofagus dombeyi, a keystone species of the Patagonian Andes, in secondary forests in Argentinian northern Patagonia, particularly addressing the role of disturbance through grazing by livestock at various intensities. We test the hypothesis that the regeneration of this tree species is favored by grazing impact and, thus, disturbance of the herb layer and soil surface. In support of our hypothesis, Nothofagus dombeyi regeneration was significantly higher in terms of individuals and height classes in moderately grazed forests. Multivariate analysis shows significant positive effects of moderate grazing pressure, herb layer cover, and the occurrence of bare soil on the regeneration of Nothofagus dombeyi. Our results show that an integration of livestock grazing and forest regeneration is possible and that agroforestry systems can be an adequate management option for stakeholders in the region. A grazing management can also be part of a forest fire prevention strategy. However, the regeneration success and grazing pressure should be continuously monitored.

Published

2023

8. Biodiversity and ecosystem functions depend on environmental conditions and resources rather than the geodiversity of a tropical biodiversity hotspot

Author

Christine I. B. Wallis, Yvonne C. Tiede, Erwin Beck, Katrin Böhning-Gaese, Roland Brandl, David A. Donoso, Carlos I. Espinosa, Andreas Fries, Jürgen Homeier, Diego Inclan, Christoph Leuschner, Mark Maraun, Katrin Mikolajewski, Eike Lena Neuschulz, Stefan Scheu, Matthias Schleuning, Juan P. Suárez, Boris A. Tinoco, Nina Farwig, and Jörg Bendix

Subjects

Medicine, Science

Abstract

Abstract Biodiversity and ecosystem functions are highly threatened by global change. It has been proposed that geodiversity can be used as an easy-to-measure surrogate of biodiversity to guide conservation management. However, so far, there is mixed evidence to what extent geodiversity can predict biodiversity and ecosystem functions at the regional scale relevant for conservation planning. Here, we analyse how geodiversity computed as a compound index is suited to predict the diversity of four taxa and associated ecosystem functions in a tropical mountain hotspot of biodiversity and compare the results with the predictive power of environmental conditions and resources (climate, habitat, soil). We show that combinations of these environmental variables better explain species diversity and ecosystem functions than a geodiversity index and identified climate variables as more important predictors than habitat and soil variables, although the best predictors differ between taxa and functions. We conclude that a compound geodiversity index cannot be used as a single surrogate predictor for species diversity and ecosystem functions in tropical mountain rain forest ecosystems and is thus little suited to facilitate conservation management at the regional scale. Instead, both the selection and the combination of environmental variables are essential to guide conservation efforts to safeguard biodiversity and ecosystem functions.

Published

2021

9. Three‐dimensional stratification pattern in an old‐growth lowland forest: How does height in canopy and season influence temperate bat activity?

Author

Maude Erasmy, Christoph Leuschner, Niko Balkenhol, and Markus Dietz

Subjects

Bialowieza forest, gaps, insectivorous bats, seasonality, three‐dimensional habitat use, Ecology, QH540-549.5

Abstract

Abstract The study of animal–habitat interactions is of primary importance for the formulation of conservation recommendations. Flying, gliding, and climbing animals have the ability to exploit their habitat in a three‐dimensional way, and the vertical canopy structure in forests plays an essential role for habitat suitability. Forest bats as flying mammals may seasonally shift their microhabitat use due to differing energy demands or changing prey availability, but the patterns are not well understood. We investigated three‐dimensional and seasonal habitat use by insectivorous bats in a temperate lowland old‐growth forest, the Belovezhskaya Pushcha in Belarus. We acoustically sampled broadleaved and mixed coniferous plots in the forest interior and in gaps in three heights during two reproductive periods (pregnancy/lactation vs. postlactation). In canopy gaps, vertical stratification in bat activity was less pronounced than in the forest interior. Vertical activity patterns differed among species. The upper canopy levels were important foraging habitats for the open‐space forager guild and for some edge‐space foragers like the Barbastelle bat Barbastella barbastellus and the soprano pipistrelle Pipistrellus pygmaeus. Myotis species had highest activity levels near the ground in forest gaps. Moreover, we found species‐dependent seasonal microhabitat shifts. Generally, all species and species groups considered except Myotis species showed higher activity levels during postlactation. Myotis species tended toward higher activity in the forest interior during postlactation. P. pygmaeus switched from high activity levels in the upper canopy during pregnancy and lactation to high activity levels near the ground during postlactation. We conclude that a full comprehension of forest bat habitat use is only possible when height in canopy and seasonal patterns are considered.

Published

2021

10. Soil carbon and nutrient stocks under Scots pine plantations in comparison to European beech forests: a paired-plot study across forests with different management history and precipitation regimes

Author

Marco Diers, Robert Weigel, Heike Culmsee, and Christoph Leuschner

Subjects

Basic cations, Fagus sylvatica, Forest history, Nitrogen, Paired plots, Pinus sylvestris, Ecology, QH540-549.5

Abstract

Abstract Background Organic carbon stored in forest soils (SOC) represents an important element of the global C cycle. It is thought that the C storage capacity of the stable pool can be enhanced by increasing forest productivity, but empirical evidence in support of this assumption from forests differing in tree species and productivity, while stocking on similar substrate, is scarce. Methods We determined the stocks of SOC and macro-nutrients (nitrogen, phosphorus, calcium, potassium and magnesium) in nine paired European beech/Scots pine stands on similar Pleistocene sandy substrates across a precipitation gradient (560–820 mm∙yr− 1) in northern Germany and explored the influence of tree species, forest history, climate, and soil pH on SOC and nutrient pools. Results While the organic layer stored on average about 80% more C under pine than beech, the pools of SOC and total N in the total profile (organic layer plus mineral soil measured to 60 cm and extrapolated to 100 cm) were greater under pine by about 40% and 20%, respectively. This contrasts with a higher annual production of foliar litter and a much higher fine root biomass in beech stands, indicating that soil C sequestration is unrelated to the production of leaf litter and fine roots in these stands on Pleistocene sandy soils. The pools of available P and basic cations tended to be higher under beech. Neither precipitation nor temperature influenced the SOC pool, whereas tree species was a key driver. An extended data set (which included additional pine stands established more recently on former agricultural soil) revealed that, besides tree species identity, forest continuity is an important factor determining the SOC and nutrient pools of these stands. Conclusion We conclude that tree species identity can exert a considerable influence on the stocks of SOC and macronutrients, which may be unrelated to productivity but closely linked to species-specific forest management histories, thus masking weaker climate and soil chemistry effects on pool sizes.

Published

2021

11. Leaf trait variation in species-rich tropical Andean forests

Author

Jürgen Homeier, Tabea Seeler, Kerstin Pierick, and Christoph Leuschner

Subjects

Medicine, Science

Abstract

Abstract Screening species-rich communities for the variation in functional traits along environmental gradients may help understanding the abiotic drivers of plant performance in a mechanistic way. We investigated tree leaf trait variation along an elevation gradient (1000–3000 m) in highly diverse neotropical montane forests to test the hypothesis that elevational trait change reflects a trend toward more conservative resource use strategies at higher elevations, with interspecific trait variation decreasing and trait integration increasing due to environmental filtering. Analysis of trait variance partitioning across the 52 tree species revealed for most traits a dominant influence of phylogeny, except for SLA, leaf thickness and foliar Ca, where elevation was most influential. The community-level means of SLA, foliar N and Ca, and foliar N/P ratio decreased with elevation, while leaf thickness and toughness increased. The contribution of intraspecific variation was substantial at the community level in most traits, yet smaller than the interspecific component. Both within-species and between-species trait variation did not change systematically with elevation. High phylogenetic diversity, together with small-scale edaphic heterogeneity, cause large interspecific leaf trait variation in these hyper-diverse Andean forests. Trait network analysis revealed increasing leaf trait integration with elevation, suggesting stronger environmental filtering at colder and nutrient-poorer sites.

Published

2021

12. Weed Seed Banks in Intensive Farmland and the Influence of Tillage, Field Position, and Sown Flower Strips

Author

Liesa Schnee, Laura M. E. Sutcliffe, Christoph Leuschner, and Tobias W. Donath

Subjects

agrobiodiversity, arable weeds, field edge, field interior, seed bank, segetal plants, Agriculture

Abstract

Agricultural intensification has caused once diverse arable fields to become species-poor. Their seed banks, which are fundamental for re-establishment and maintenance of plant communities in such repeatedly disturbed environments, are now largely depleted. In order to advise farmers on the successful implementation of agri-environmental measures, as well as reduce potential subsequent costs of continued weed control, understanding seed bank dynamics in relation to aboveground vegetation is essential. We (1) investigated the change in seed bank composition in the field edge and the interior, and (2) analyzed the seed bank in flower strips and adjacent fields in relation to the aboveground vegetation on intensively managed arable farms across Germany. Low-tillage systems contained more plant species and higher seed densities in the seed bank than regularly ploughed fields. Species diversity at the field edge was higher than in the field interior, with a continuous decrease in the number of species and seed density within the first 2 m from the edge. Flower strips can lead to an enrichment of the seed bank, but it is driven by the strong rise in a few common species such as Chenopodium album. To cultivate successful flower strips, we recommend close onsite monitoring, as well as rapid intervention in the case of weed infestation.

Published

2023

13. Did stand opening 60 years ago predispose a European beech population to death?

Author

Choimaa Dulamsuren, Banzragch Bat-Enerel, Peter Meyer, and Christoph Leuschner

Subjects

climate change, drought, early-warning signal of tree death, land use legacy, logging, short-term ring width variation, Forestry, SD1-669.5, Plant ecology, QK900-989

Abstract

Widespread increases in tree mortality have fueled the debate on the mechanisms of heat- and drought-related tree death. While much research focused on the immediate causes of tree death, the role of predisposing factors for death is not well understood. We employed tree-ring and climate sensitivity analysis of growth to study the importance of legacy effects of past disturbances for growth patterns and a recent mortality burst in a protected European beech (Fagus sylvatica) forest, comparing groups of live and recently died trees in the same stand. Live and dead trees showed a decade-long decrease in radial growth since the severe 1976 drought, which indicates that the high mortality in the last two decades is not solely caused by recent drought spells, but that trees were apparently predisposed by previous events to death decades later. An even more distant event than the 1976 drought that has imprinted on the chronologies is the severe 1947 drought in combination with extensive logging at that time. It appears that stand opening 60 and 40 years ago due to high immediate drought mortality in conjunction with heavy logging resulted in much higher inter-annual ring width variability with more extreme negative and positive pointer years in the subsequent years, and led to permanent reduction in tree health. We identified the first derivative of the ring width curve as the most reliable early-warning signal of a predisposition to drought-induced death, while inter-annual growth variability and growth resistance and resilience to drought were less suited. We suggest that the causes of recent climate warming-related dieback of beech and other temperate hardwood forests may only be fully grasped, when the imprint of past stress events on growth and vitality is understood. The physiological mechanisms causing legacy effects with long delay of death require further study.

Published

2022

14. Changes in the Thermal and Hydrometeorological Forest Growth Climate During 1948–2017 in Northern Germany

Author

Banzragch Bat-Enerel, Robert Weigel, and Christoph Leuschner

Subjects

climate aridification, climatic water balance, June precipitation, SPEI trend, temperature increase, tree growth, Forestry, SD1-669.5, Environmental sciences, GE1-350

Abstract

Recent severe droughts and climate change projections have caused rising worries about the impacts of a warmer and drier climate on forests and the future of timber production. While recent trends in thermal and hydrometeorological climate factors have been studied in many regions on earth, less is known about long-term change in climate variables most relevant for tree health and productivity, i.e., temperature (T), precipitation (P), climatic water balance (CWB), and SPEI aridity index in early and mid-summer, when leaf unfolding and peak stem growth take place. Here, we analyze T, P, CWB, and SPEI trends separately for all growing season months (April-September) during the 1948–1982 (before the recent warming) and 1983–2017 periods (after the onset of warming) in their spatial variation across the North German Lowlands based on a dense climate station network. While trends in thermal and hydrometeorological variables were weak from 1948 to 1982, we find a significant decrease in April precipitation and increase in July precipitation from 1983 to 2017 throughout much of the study region, while June precipitation has decreased locally by 10 mm or more (or up to 20%). The cumulated growing-season CWB has deteriorated by up to 30 mm from 1948–1982 to 1983–2017 in most of the region except at the North Sea coast, where it became more favorable. Recent climate aridification is more pronounced in the drier South-east of the study region with a more continental climate, as indicated by stronger negative P, CWB, and SPEI trends for April, May, and June. We conclude that water availability especially in the physiologically important months April and June has deteriorated in the larger part of the North German Lowlands since the 1980s, increasingly impairing hydrometeorological forest growth conditions. The identified trends may serve as early-warning signals of anticipated future loss in tree vitality.

Published

2022

15. Trade-offs between multifunctionality and profit in tropical smallholder landscapes

Author

Ingo Grass, Christoph Kubitza, Vijesh V. Krishna, Marife D. Corre, Oliver Mußhoff, Peter Pütz, Jochen Drescher, Katja Rembold, Eka Sulpin Ariyanti, Andrew D. Barnes, Nicole Brinkmann, Ulrich Brose, Bernhard Brümmer, Damayanti Buchori, Rolf Daniel, Kevin F. A. Darras, Heiko Faust, Lutz Fehrmann, Jonas Hein, Nina Hennings, Purnama Hidayat, Dirk Hölscher, Malte Jochum, Alexander Knohl, Martyna M. Kotowska, Valentyna Krashevska, Holger Kreft, Christoph Leuschner, Neil Jun S. Lobite, Rawati Panjaitan, Andrea Polle, Anton M. Potapov, Edwine Purnama, Matin Qaim, Alexander Röll, Stefan Scheu, Dominik Schneider, Aiyen Tjoa, Teja Tscharntke, Edzo Veldkamp, and Meike Wollni

Subjects

Science

Abstract

Identifying economic and ecological trade-offs of land-use transitions is important to ensure sustainability. Here, Grass et al. find biodiversity-profit trade-offs in tropical land-use transitions in Sumatra, and show that targeted landscape planning is needed to increase land-use efficiency while ensuring socio-ecological sustainability.

Published

2020

16. Quantifying old-growthness of lowland European beech forests by a multivariate indicator for forest structure

Author

Peter Meyer, Maria Aljes, Heike Culmsee, Eike Feldmann, Jonas Glatthorn, Christoph Leuschner, and Heike Schneider

Subjects

Natural forest development, Conservation status, Forest index, Ecology, QH540-549.5

Abstract

Quantifying the degree of old-growthness of forests is reasonable to assess their conservation value and guide management decisions. This study aimed at developing and applying an indicator to quantify the old-growthness of forest structure on potential beech forest sites in Central Europe which exhibit a long history of forest management. A set of structural variables was derived from sample plot inventories in European primeval beech forests in Eastern Slovakia (classified as old-growth) and 39 comparison stands of different management intensity, age and tree species composition in the North German lowlands. The comparison stands were arranged in triplets, consisting of i) a > 100 year old European beech forest left to natural development (ND), ii) 80 to 100 year old Scots pine forest with a certain amount of deciduous trees in the understory (OP), and iii)

Published

2021

17. Effects of Wood Hydraulic Properties on Water Use and Productivity of Tropical Rainforest Trees

Author

Martyna M. Kotowska, Roman M. Link, Alexander Röll, Dietrich Hertel, Dirk Hölscher, Pierre-André Waite, Gerald Moser, Aiyen Tjoa, Christoph Leuschner, and Bernhard Schuldt

Subjects

functional traits, growth rate, hydraulic efficiency, net primary production, sap flux density, structural equation modeling, Forestry, SD1-669.5, Environmental sciences, GE1-350

Abstract

The efficiency of the water transport system in trees sets physical limits to their productivity and water use. Although the coordination of carbon assimilation and hydraulic functions has long been documented, the mutual inter-relationships between wood anatomy, water use and productivity have not yet been jointly addressed in comprehensive field studies. Based on observational data from 99 Indonesian rainforest tree species from 37 families across 22 plots, we analyzed how wood anatomy and sap flux density relate to tree size and wood density, and tested their combined influence on aboveground biomass increment (ABI) and daily water use (DWU). Results from pairwise correlations were compared to the outcome of a structural equation model (SEM). Across species, we found a strong positive correlation between ABI and DWU. Wood hydraulic anatomy was more closely related to these indicators of plant performance than wood density. According to the SEM, the common effect of average tree size and sap flux density on the average stem increment and water use of a species was sufficient to fully explain the observed correlation between these variables. Notably, after controlling for average size, only a relatively small indirect effect of wood properties on stem increment and water use remained that was mediated by sap flux density, which was significantly higher for species with lighter and hydraulically more efficient wood. We conclude that wood hydraulic traits are mechanistically linked to water use and productivity via their influence on sap flow, but large parts of these commonly observed positive relationships can be attributed to confounding size effects.

Published

2021

18. Climatic control of high-resolution stem radius changes in a drought-limited southern boreal forest

Author

Choimaa Dulamsuren, Heinz Coners, Christoph Leuschner, and Markus Hauck

Subjects

Ecology, Physiology, Forestry, Plant Science

Abstract

Key message Stem radius changes measured at high temporal resolution in a drought-limited southern boreal forest were primarily related to soil temperature and partly soil moisture variation, but only weakly to VPD. Abstract Forest productivity at the southern fringe of the boreal forest biome in Inner Asia is strongly drought-limited, as is evident from dendrochronological analyses. Using electronic point dendrometers, we studied the climate response of stem radius changes at high temporal resolution (10-min intervals) in a mixed larch–birch forest in northern Mongolia in a drought year and two subsequent moist years. Larch trees showed stronger stem radius fluctuations than birches, and this difference was more pronounced in dry than in moist years. Stem radius changes were most tightly related to soil temperature variation, while soil moisture was the dominant controlling factor only in birch in the dry year. Correlations with the atmospheric vapor pressure deficit (VPD), and even more so with air temperature, were much weaker. While the linkage between radius change and VPD might primarily reflect diurnal transpiration-driven stem shrinkage and expansion, soil temperature is thought to directly affect cambial cell division and elongation during wood formation. We conclude that the phenology of stemwood increment is strongly controlled by soil temperature even in drought-limited southern boreal forests under continental climate due to the combination of cold and dry climate.

Published

2023

19. Biomass, Morphology, and Dynamics of the Fine Root System Across a 3,000-M Elevation Gradient on Mt. Kilimanjaro

Author

Natalia Sierra Cornejo, Dietrich Hertel, Joscha N. Becker, Andreas Hemp, and Christoph Leuschner

Subjects

afroalpine heathland, fine root biomass, fine root production, root economics spectrum, root traits, root:shoot ratio, Plant culture, SB1-1110

Abstract

Fine roots (≤2 mm) consume a large proportion of photosynthates and thus play a key role in the global carbon cycle, but our knowledge about fine root biomass, production, and turnover across environmental gradients is insufficient, especially in tropical ecosystems. Root system studies along elevation transects can produce valuable insights into root trait-environment relationships and may help to explore the evidence for a root economics spectrum (RES) that should represent a trait syndrome with a trade-off between resource acquisitive and conservative root traits. We studied fine root biomass, necromass, production, and mean fine root lifespan (the inverse of fine root turnover) of woody plants in six natural tropical ecosystems (savanna, four tropical mountain forest types, tropical alpine heathland) on the southern slope of Mt. Kilimanjaro (Tanzania) between 900 and 4,500 m a.s.l. Fine root biomass and necromass showed a unimodal pattern along the slope with a peak in the moist upper montane forest (~2,800 m), while fine root production varied little between savanna and upper montane forest to decrease toward the alpine zone. Root:shoot ratio (fine root biomass and production related to aboveground biomass) in the tropical montane forest increased exponentially with elevation, while it decreased with precipitation and soil nitrogen availability (decreasing soil C:N ratio). Mean fine root lifespan was lowest in the ecosystems with pronounced resource limitation (savanna at low elevation, alpine heathland at high elevation) and higher in the moist and cool forest belt (~1,800–3,700 m). The variation in root traits across the elevation gradient fits better with the concept of a multi-dimensional RES, as root tissue density and specific root length showed variable relations to each other, which does not agree with a simple trade-off between acquisitive and conservative root traits. In conclusion, despite large variation in fine root biomass, production, and morphology among the different plant species and ecosystems, a general belowground shift in carbohydrate partitioning is evident from 900 to 4,500 m a.s.l., suggesting that plant growth is increasingly limited by nutrient (probably N) shortage toward higher elevations.

Published

2020

20. Implementing a New Rubber Plant Functional Type in the Community Land Model (CLM5) Improves Accuracy of Carbon and Water Flux Estimation

Author

Ashehad A. Ali, Yuanchao Fan, Marife D. Corre, Martyna M. Kotowska, Evelyn Preuss-Hassler, Andi Nur Cahyo, Fernando E. Moyano, Christian Stiegler, Alexander Röll, Ana Meijide, Alexander Olchev, Andre Ringeler, Christoph Leuschner, Rahmi Ariani, Tania June, Suria Tarigan, Holger Kreft, Dirk Hölscher, Chonggang Xu, Charles D. Koven, Katherine Dagon, Rosie A. Fisher, Edzo Veldkamp, and Alexander Knohl

Subjects

rubber trees, intraspecies differences, carbon–water cycling, CLM, earth system model, land-use change, Agriculture

Abstract

Rubber plantations are an economically viable land-use type that occupies large swathes of land in Southeast Asia that have undergone conversion from native forest to intensive plantation forestry. Such land-use change has a strong impact on carbon, energy, and water fluxes in ecosystems, and uncertainties exist in the modeling of future land-use change impacts on these fluxes due to the scarcity of measured data and poor representation of key biogeochemical processes. In this current modeling effort, we utilized the Community Land Model Version 5 (CLM5) to simulate a rubber plant functional type (PFT) by comparing the baseline parameter values of tropical evergreen PFT and tropical deciduous PFT with a newly developed rubber PFT (focused on the parameterization and modification of phenology and allocation processes) based on site-level observations of a rubber clone in Indonesia. We found that the baseline tropical evergreen and baseline tropical deciduous functions and parameterizations in CLM5 poorly simulate the leaf area index, carbon dynamics, and water fluxes of rubber plantations. The newly developed rubber PFT and parametrizations (CLM-rubber) showed that daylength could be used as a universal trigger for defoliation and refoliation of rubber plantations. CLM-rubber was able to predict seasonal patterns of latex yield reasonably well, despite highly variable tapping periods across Southeast Asia. Further, model comparisons indicated that CLM-rubber can simulate carbon and energy fluxes similar to the existing rubber model simulations available in the literature. Our modeling results indicate that CLM-rubber can be applied in Southeast Asia to examine variations in carbon and water fluxes for rubber plantations and assess how rubber-related land-use changes in the tropics feedback to climate through carbon and water cycling.

Published

2022

21. Classifying development stages of primeval European beech forests: is clustering a useful tool?

Author

Jonas Glatthorn, Eike Feldmann, Vath Tabaku, Christoph Leuschner, and Peter Meyer

Subjects

Fagus sylvatica, Forest dynamics, Spatial observation scale, Moving window, Primeval forests, Forest development cycle, Ecology, QH540-549.5

Abstract

Abstract Background Old-growth and primeval forests are passing through a natural development cycle with recurring stages of forest development. Several methods for assigning patches of different structure and size to forest development stages or phases do exist. All currently existing classification methods have in common that a priori assumptions about the characteristics of certain stand structural attributes such as deadwood amount are made. We tested the hypothesis that multivariate datasets of primeval beech forest stand structure possess an inherent, aggregated configuration of data points with individual clusters representing forest development stages. From two completely mapped primeval beech forests in Albania, seven ecologically important stand structural attributes characterizing stand density, regeneration, stem diameter variation and amount of deadwood are derived at 8216 and 9666 virtual sampling points (moving window, focal filtering). K-means clustering is used to detect clusters in the datasets (number of clusters (k) between 2 and 5). The quality of the single clustering solutions is analyzed with average silhouette width as a measure for clustering quality. In a sensitivity analysis, clustering is done with datasets of four different spatial scales of observation (200, 500, 1000 and 1500 m2, circular virtual plot area around sampling points) and with two different kernels (equal weighting of all objects within a plot vs. weighting by distance to the virtual plot center). Results The clustering solutions succeeded in detecting and mapping areas with homogeneous stand structure. The areas had extensions of more than 200 m2, but differences between clusters were very small with average silhouette widths of less than 0.28. The obtained datasets had a homogeneous configuration with only very weak trends for clustering. Conclusions Our results imply that forest development takes place on a continuous scale and that discrimination between development stages in primeval beech forests is splitting continuous datasets at selected thresholds. For the analysis of the forest development cycle, direct quantification of relevant structural features or processes might be more appropriate than classification. If, however, the study design demands classification, our results can justify the application of conventional forest development stage classification schemes rather than clustering.

Published

2018

22. Both climate sensitivity and growth trend of European beech decrease in the North German Lowlands, while Scots pine still thrives, despite growing sensitivity

Author

Marco Diers, Robert Weigel, and Christoph Leuschner

Subjects

Ecology, Physiology, Forestry, Plant Science

Abstract

Key message Beech and pine respond differently to climate change. June precipitation is of particular influence for beech, and February/March temperature for pine. Abstract Climate warming exposes forests to increasing abiotic stress, demanding for difficult silvicultural decisions about the right choice of future timber species. Scots pine (Pinus sylvestris) and European beech (Fagus sylvatica) are major timber species in the North German Lowlands, which have suffered from recent hot droughts, thus raising concern about their suitability for future production forests in the region. We investigated the climate sensitivity of tree growth and long-term growth trends of ten paired beech and pine forests along a precipitation gradient in the North German Lowlands with the aim to compare the species’ climate sensitivity and to search for species-specific climatic thresholds. In the majority of beech stands, basal area increment (BAI) has lost its positive trend since the 1980s or growth declined since then, while the BAI of pine has continually increased. Long-term change in June precipitation is in the study region a more important determinant of beech growth trends than the amount of MAP, while pine growth is largely dependent on the warmth of February/March. Yet, pine growth is also sensitive to dry mid summers, with sensitivity increasing toward low MAP. Climate sensitivity of growth has significantly declined since the 1980s in beech, while the dominant drought signal of June persisted in pine. We conclude that recent climate change is affecting radial growth of beech and pine differently with both species revealing signs of vulnerability to hot droughts, suggesting for the drier part of the study region the preference of more drought-tolerant hardwood timber species over beech and pine.

Published

2022

23. Higher growth synchrony and climate change‐sensitivity in European beech and silver linden than in temperate oaks

Author

Jan Kasper, Christoph Leuschner, Helge Walentowski, and Robert Weigel

Subjects

Ecology, Ecology, Evolution, Behavior and Systematics

Published

2022

24. Stand dynamics of the drought-affected floodplain forests of Araguaia River, Brazilian Amazon

Author

Jürgen Homeier, Dariusz Kurzatkowski, and Christoph Leuschner

Subjects

Amazon, Diameter growth, Dry season, Flooding regime, Mortality rate, Productivity, Ecology, QH540-549.5

Abstract

Abstract Background The floodplain forests of Araguaia River, a clear-water river in the southeastern Amazon (Tocantins State, Brazil), are characterized by seasonal flooding up to 3.5 m height, low nutrient levels in the water, and seasonal drought periods of 4–5 months. Methods We studied the forest dynamics (tree diameter growth, tree mortality and recruitment) of this unique forest ecosystem over a 5-year period by repeated censuses in 12 permanent plots established along a flooding gradient. Results The cumulative basal area in the plots increased by 0.84 (±0.45) m2∙ha–1∙yr–1 (mean ±SD) in the annually-flooded (AF) plots in lower terrain and by 0.69 (±1.00) m2∙ha–1∙yr–1 in the higher non-annually flooded (NAF) plots, corresponding to an aboveground biomass increase of 0.81 (±0.57) and 0.69 (±1.58) Mg∙ha–1∙yr–1 in the AF and NAF plots, indicating a recent carbon sink in the biomass. Mean diameter growth rate was 1.8 (±0.44) mm∙yr–1 in the AF and 2.0 (±0.56) mm∙yr–1 in the NAF plots (corresponding to a coarse wood production of 1.53 (±1.29) and 2.02 (±0.52) Mg∙ha–1∙yr–1), indicating no flooding effect on radial growth. Mean mortality rates in the 5-year period were 1.9 (±0.37)%∙yr–1 in the AF plots and 1.8 (±0.87)%∙yr–1 in the NAF plots with no differences along the flooding gradient. Highest mortalities were registered in the AF plots for the 10–20 cm dbh class (2.4%∙yr–1), likely as a consequence of flooding, and in the NAF plots for the 40–50 cm dbh class (3.0%∙yr–1), probably mainly caused by ENSO-related droughts. Conclusions We conclude that these drought-affected tropical floodplain forests have a lower standing biomass and aboveground productivity than central Amazonian floodplain forests in more humid climates, and the imprint of the flooding gradient on stand dynamics is relatively weak, which may result from the lower flooding height and the interaction of flooding with low nutrient supply and periodic drought.

Published

2017

25. Assessing future suitability of tree species under climate change by multiple methods: a case study in southern Germany

Author

Helge Walentowski, Wolfgang Falk, Tobias Mette, Jörg Kunz, Achim Bräuning, Cathrin Meinardus, Christian Zang, Laura M.E. Sutcliffe, and Christoph Leuschner

Subjects

broadleaf forests, climate modelling, dendrochronology, drought tolerance, ecological niche, ellenberg indicator values, Forestry, SD1-669.5

Abstract

We compared results derived using three different approaches to assess the suitability of common tree species on the Franconian Plateau in southern Germany under projected warmer and drier climate conditions in the period 2061-2080. The study area is currently a relatively warm and dry region of Germany. We calculated species distribution models (SDMs) using information on species’ climate envelopes to predict regional species spectra under 63 different climate change scenarios. We complemented this with fine-scale ecological niche analysis using data from 51 vegetation surveys in seven forest reserves in the study area, and tree-ring analysis (TRA) from local populations of five tree species to quantify their sensitivity to climatic extreme years. The SDMs showed that predicted future climate change in the region remains within the climate envelope of certain species (e.g. Quercus petraea), whilst for e.g. Fagus sylvatica, future climate conditions in one third of the scenarios are too warm and dry. This was confirmed by the TRA: sensitivity to drought periods is lower for Q. petraea than for F. sylvatica. The niche analysis shows that the local ecological niches of Quercus robur and Fraxinus excelsior are mainly characterized by soils providing favorable water supply than by climate, and Pinus sylvestris (planted) is strongly influenced by light availability. The best adapted species for a warmer and potentially drier climate in the study region are Acer campestre, Sorbus torminalis, S. aria, Ulmus minor, and Tilia platyphyllos, which should therefore play a more prominent role in future climate-resilient mixed forest ecosystems.

Published

2017

26. Temperature effects on root exudation in mature beech (Fagus sylvatica L.) forests along an elevational gradient

Author

Christoph Leuschner, Timo Tückmantel, and Ina C Meier

Subjects

Soil Science, Plant Science

Abstract

Aims Root exudation may have a large impact on soil biological activity and nutrient cycling. Recent advances in in situ-measurement techniques have enabled deeper insights into the impact of tree root exudation on rhizosphere processes, but the abiotic and biotic controls of exudation rate remain poorly understood. We explored the temperature dependence of root exudation in mature beech (Fagus sylvatica L.) trees. Methods We measured fine root exudation in seven beech forests along an elevational gradient (310–800 m a.s.l.) and related carbon (C)-flux rates to mean daily temperature, actual precipitation, mean summer temperature (MST) and precipitation (MAP), soil moisture (SWC), and stand structure. Results Average mass-specific exudation (averaged over all sampling dates) ranged from 12.2 µg C g−1 h−1 to 21.6 µg C g−1 h−1 with lowest rates measured at highest elevations and peak rates at mid-elevation (490 m). Regression analyses showed a highly significant positive effect of site-specific daily air and soil temperature on exudation rates (p −1 h−1 per 1 °C-temperature increase, while the relation to mean summer or annual temperature and mean temperature of the measuring year was less tight. Exudation decreased with increases in mean annual precipitation and soil moisture, but increased with increasing stem density. Conclusions The root exudation rate of beech trees roughly triples between 10 °C and 20 °C mean daily temperature, evidencing a large temperature influence on root-borne C flux to the soil.

Published

2022

27. The Role of Low Soil Temperature for Photosynthesis and Stomatal Conductance of Three Graminoids From Different Elevations

Author

Leonie Göbel, Heinz Coners, Dietrich Hertel, Sandra Willinghöfer, and Christoph Leuschner

Subjects

adaptation to cold soil, leaf respiration, photosynthesis, soil frost, stomatal conductance, transpiration, Plant culture, SB1-1110

Abstract

In high-elevation grasslands, plants can encounter periods with high air temperature while the soil remains cold, which may lead to a temporary mismatch in the physiological activity of leaves and roots. In a climate chamber experiment with graminoid species from three elevations (4400, 2400, and 250 m a.s.l.), we tested the hypothesis that soil temperature can influence photosynthesis and stomatal conductance independently of air temperature. Soil monoliths with swards of Kobresia pygmaea (high alpine), Nardus stricta (lower alpine), and Deschampsia flexuosa (upper lowland) were exposed to soil temperatures of 25, 15, 5, and -2°C and air temperatures of 20 and 10°C for examining the effect of independent soil and air temperature variation on photosynthesis, leaf dark respiration, and stomatal conductance and transpiration. Soil frost (-2°C) had a strong negative effect on gas exchange and stomatal conductance in all three species, independent of the elevation of origin. Leaf dark respiration was stimulated by soil frost in D. flexuosa, but not in K. pygmaea, which also had a lower temperature optimum of photosynthesis. Soil cooling from 15 to 5°C did not significantly reduce stomatal conductance and gas exchange in any of the species. We conclude that all three graminoids are able to maintain a relatively high root water uptake in cold, non-frozen soil, but the high-alpine K. pygmaea seems to be especially well adapted to warm shoot – cold root episodes, as it has a higher photosynthetic activity at 10 than 20°C air temperature and does not up-regulate leaf dark respiration upon soil freezing, as was observed in the grasses from warmer climates.

Published

2019

28. Auswirkungen von Biodiversitätsmaßnahmen auf die Segetalflora auf intensiv bewirtschafteten landwirtschaftlichen Flächen - Ergebnisse aus dem F.R.A.N.Z.-Projekt

Author

Laura Sutcliffe and Christoph Leuschner

Subjects

Ecology, General Environmental Science

Published

2022

29. Land-use choices follow profitability at the expense of ecological functions in Indonesian smallholder landscapes

Author

Yann Clough, Vijesh V. Krishna, Marife D. Corre, Kevin Darras, Lisa H. Denmead, Ana Meijide, Stefan Moser, Oliver Musshoff, Stefanie Steinebach, Edzo Veldkamp, Kara Allen, Andrew D. Barnes, Natalie Breidenbach, Ulrich Brose, Damayanti Buchori, Rolf Daniel, Reiner Finkeldey, Idham Harahap, Dietrich Hertel, A. Mareike Holtkamp, Elvira Hörandl, Bambang Irawan, I. Nengah Surati Jaya, Malte Jochum, Bernhard Klarner, Alexander Knohl, Martyna M. Kotowska, Valentyna Krashevska, Holger Kreft, Syahrul Kurniawan, Christoph Leuschner, Mark Maraun, Dian Nuraini Melati, Nicole Opfermann, César Pérez-Cruzado, Walesa Edho Prabowo, Katja Rembold, Akhmad Rizali, Ratna Rubiana, Dominik Schneider, Sri Sudarmiyati Tjitrosoedirdjo, Aiyen Tjoa, Teja Tscharntke, and Stefan Scheu

Subjects

Science

Abstract

Small-scale farmers in Southeast Asia are increasingly turning to monocultures of oil palm and rubber to maximize income. Clough and colleagues demonstrate that this land-use change in Indonesia comes at a cost to a wide array of ecosystem functions and biodiversity.

Published

2016

30. Soil water availability and branch age explain variability in xylem safety of European beech in Central Europe

Author

Greta Weithmann, Roman M. Link, Bat-Enerel Banzragch, Laura Würzberg, Christoph Leuschner, and Bernhard Schuldt

Subjects

Europe, Soil, Xylem, Fagus, Water, Ecology, Evolution, Behavior and Systematics, Droughts, Trees

Abstract

Xylem embolism resistance has been identified as a key trait with a causal relation to drought-induced tree mortality, but not much is known about its intra-specific trait variability (ITV) in dependence on environmental variation. We measured xylem safety and efficiency in 300 European beech (Fagus sylvatica L.) trees across 30 sites in Central Europe, covering a precipitation reduction from 886 to 522 mm year−1. A broad range of variables that might affect embolism resistance in mature trees, including climatic and soil water availability, competition, and branch age, were examined. The average P50 value varied by up to 1 MPa between sites. Neither climatic aridity nor structural variables had a significant influence on P50. However, P50 was less negative for trees with a higher soil water storage capacity, and positively related to branch age, while specific conductivity (Ks) was not significantly associated with either of these variables. The greatest part of the ITV for xylem safety and efficiency was attributed to random variability within populations. We conclude that the influence of site water availability on P50 and Ks is low in European beech, and that the high degree of within-population variability for P50, partly due to variation in branch age, hampers the identification of a clear environmental signal.

Published

2022

31. Long-Term Impact of Intensive Agriculture on Earthworm and Microbial Communities of Cropped Fields and Field Margins in Northern Germany

Author

Esther Klingenberg, Christoph Leuschner, Laura Sutcliffe, Cara Schulte, and Mark Maraun

Published

2023

32. Current State and Drivers of Arable Plant Diversity in Conventionally Managed Farmland in Northwest Germany

Author

Alexander Wietzke, Clara-Sophie van Waveren, Erwin Bergmeier, Stefan Meyer, and Christoph Leuschner

Subjects

adjacent habitats, agricultural management, biodiversity loss, cereals, farmland phytodiversity, herbicides, Biology (General), QH301-705.5

Abstract

Agricultural intensification has led to dramatic diversity losses and impoverishment of the arable vegetation in much of Europe. We analyzed the status of farmland phytodiversity and its determinants in 2016 in northwest Germany by surveying 200 conventionally managed fields cultivated with seven crops. The study was combined with an analysis of edaphic (soil yield potential), agronomic (crop cover, fertilizer and herbicide use) and landscape factors (adjacent habitats). In total, we recorded 150 non-crop plant species, many of them nitrophilous generalist species, while species of conservation value were almost completely absent. According to a post-hoc pairwise comparison of the mixed model results, the cultivation of rapeseed positively influenced non-crop plant species richness as compared to winter cereals (wheat, barley, rye and triticale; data pooled), maize or potato. The presence of grassy strips and ditch margins adjacent to fields increased plant richness at field edges presumably through spillover effects. In the field interiors, median values of non-crop plant richness and cover were only 2 species and 0.5% cover across all crops, and at the field edges 11 species and 4% cover. Agricultural intensification has wiped out non-crop plant life nearly completely from conventionally managed farmland, except for a narrow, floristically impoverished field edge strip.

Published

2020

33. Effects of Inundation, Nutrient Availability and Plant Species Diversity on Fine Root Mass and Morphology Across a Saltmarsh Flooding Gradient

Author

Regine Redelstein, Thomas Dinter, Dietrich Hertel, and Christoph Leuschner

Subjects

diversity effect, nutrient availability, root depth distribution, sediment texture, specific root area, tidal inundation gradient, Plant culture, SB1-1110

Abstract

Saltmarsh plants are exposed to multiple stresses including tidal inundation, salinity, wave action and sediment anoxia, which require specific root system adaptations to secure sufficient resource capture and firm anchorage in a temporary toxic environment. It is well known that many saltmarsh species develop large below-ground biomass (roots and rhizomes) but relations between fine roots, in particular, and the abiotic conditions in salt marshes are widely unknown. We studied fine root mass (

Published

2018

34. Primeval, natural and commercial forests in the context of biodiversity and climate protection - Part 2: The Narrative of the Climate Neutrality of Wood as a Resource

Author

Rainer Luick, Klaus Hennenberg, Christoph Leuschner, Manfred Grossmann, Eckhard Jedicke, Nicolas Schoof, and Thomas Waldenspuhl

Subjects

Ecology, General Environmental Science

Published

2021

35. Leaf trait modification in European beech trees in response to climatic and edaphic drought

Author

H John, Stefanie Hoeber, G Weithmann, D Heil, L-M Schüller, Hilmar Müller-Haubold, Christoph Leuschner, Katja Schumann, Bernhard Schuldt, and Roman M. Link

Subjects

0106 biological sciences, Specific leaf area, biology, Drought tolerance, Water, Edaphic, Plant Science, General Medicine, 15. Life on land, biology.organism_classification, 010603 evolutionary biology, 01 natural sciences, Trees, Droughts, Plant Leaves, Soil, Fagus sylvatica, Agronomy, Soil water, Fagus, Leaf size, Sample collection, Beech, Ecology, Evolution, Behavior and Systematics, 010606 plant biology & botany

Abstract

Leaf morphological and physiological traits control the carbon and water relations of mature trees and are determinants of drought tolerance, but it is not well understood how they are modified in response to water deficits. We analysed five sun-canopy leaf traits (mean leaf size (LS), specific leaf area (SLA), Huber value (HV), water potential at turgor loss point (Ψtlp ) and foliar carbon isotope signature (δ13 C)) in European beech (Fagus sylvatica L.) across three precipitation gradients sampled in moist (2010), dry (2019) and very dry (2018) summers, and tested their response to short-term water deficits (climatic water balance (CWB) preceding sample collection) and long-term water availability (mean annual precipitation (MAP), plant-available soil water capacity (AWC) and neighbourhood competition). Across the 34 sites, LS varied seven-fold (3.9-27.0 cm2 ), SLA four-fold (77.1-306.9 cm²·g-1 ) and HV six-fold (1.0-6.65 cm2 ·m-2 ). In the 2018 dataset, LS showed a negative and HV a positive relationship to MAP, which contradicts relations found in multi-species samples. Average Ψtlp ranged from -1.90 to -2.62 MPa and decreased across the sites with decreasing CWB in the month prior to measurement, as well as with decreasing MAP and AWC in 2019. Studied leaf traits varied considerably between years, suggesting that mast fruiting and the severe 2018 drought caused the formation of smaller leaves. We conclude that sun-canopy leaf traits of European beech exhibit considerable plasticity in response to climatic and edaphic aridity, and that osmotic adjustment may be an important element in the drought response strategy of this anisohydric tree species.

Published

2021

36. Urwälder, Natur- und Wirtschaftswälder im Kontext von Biodiversitäts- und Klimaschutz - Teil 2: Das Narrativ von der Klimaneutralität der Ressource Holz

Author

Rainer Luick, Klaus Hennenberg, Christoph Leuschner, Manfred Grossmann, Eckhard Jedicke, Nicolas Schoof, and Thomas Waldenspuhl

Subjects

Ecology, General Environmental Science

Published

2021

37. Primeval, natural and commercial forests in the context biodiversity and climate protection - Part 1: Functions for biodiversity and as carbon sinks and reservoirs

Author

Klaus Hennenberg, Manfred Grossmann, Nicolas Schoof, Eckhard Jedicke, Christoph Leuschner, Rainer Luick, and Thomas Waldenspuhl

Subjects

Ecology, Environmental protection, Biodiversity, Carbon sink, Environmental science, Context (language use), Climate protection, Natural (archaeology), General Environmental Science

Published

2021

38. Urwälder, Natur- und Wirtschaftswälder im Kontext von Biodiversitäts- und Klimaschutz - Teil 1: Funktionen für die biologische Vielfalt und als Kohlenstoffsenke und ‑speicher

Author

Rainer Luick, Klaus Hennenberg, Nicolas Schoof, Manfred Grossmann, Christoph Leuschner, Eckhard Jedicke, and Thomas Waldenspuhl

Subjects

Ecology, General Environmental Science

Published

2021

39. Three‐dimensional stratification pattern in an old‐growth lowland forest: How does height in canopy and season influence temperate bat activity?

Author

Christoph Leuschner, Markus Dietz, Maude Erasmy, and Niko Balkenhol

Subjects

0106 biological sciences, Canopy, Stratification (vegetation), Biology, 010603 evolutionary biology, 01 natural sciences, Temperate climate, insectivorous bats, QH540-549.5, Ecology, Evolution, Behavior and Systematics, Research Articles, Nature and Landscape Conservation, geography, geography.geographical_feature_category, Ecology, gaps, seasonality, 010604 marine biology & hydrobiology, 15. Life on land, Old-growth forest, Bialowieza forest, three‐dimensional habitat use, Lowland forest, BAT activity, Research Article

Abstract

The study of animal–habitat interactions is of primary importance for the formulation of conservation recommendations. Flying, gliding, and climbing animals have the ability to exploit their habitat in a three‐dimensional way, and the vertical canopy structure in forests plays an essential role for habitat suitability. Forest bats as flying mammals may seasonally shift their microhabitat use due to differing energy demands or changing prey availability, but the patterns are not well understood. We investigated three‐dimensional and seasonal habitat use by insectivorous bats in a temperate lowland old‐growth forest, the Belovezhskaya Pushcha in Belarus. We acoustically sampled broadleaved and mixed coniferous plots in the forest interior and in gaps in three heights during two reproductive periods (pregnancy/lactation vs. postlactation). In canopy gaps, vertical stratification in bat activity was less pronounced than in the forest interior. Vertical activity patterns differed among species. The upper canopy levels were important foraging habitats for the open‐space forager guild and for some edge‐space foragers like the Barbastelle bat Barbastella barbastellus and the soprano pipistrelle Pipistrellus pygmaeus. Myotis species had highest activity levels near the ground in forest gaps. Moreover, we found species‐dependent seasonal microhabitat shifts. Generally, all species and species groups considered except Myotis species showed higher activity levels during postlactation. Myotis species tended toward higher activity in the forest interior during postlactation. P. pygmaeus switched from high activity levels in the upper canopy during pregnancy and lactation to high activity levels near the ground during postlactation. We conclude that a full comprehension of forest bat habitat use is only possible when height in canopy and seasonal patterns are considered., We investigated three‐dimensional and seasonal habitat use by insectivorous bats in a temperate lowland old‐growth forest. We identified guild‐ and species‐specific differences in canopy height use and species‐dependent seasonal microhabitat shifts that can be explained by ecomorphological adaptations.

Published

2021

40. Spaceborne height models reveal above ground biomass changes in tropical landscapes

Author

Birgit Wessel, Christoph Leuschner, Nicolò Camarretta, Holger Kreft, Stefan Erasmi, Fabian Brambach, I Nengah Surati Jaya, Mangarah Silalahi, Martyna M. Kotowska, Michael Schlund, Jonas Hein, Department of Natural Resources, UT-I-ITC-FORAGES, and Faculty of Geo-Information Science and Earth Observation

Subjects

0106 biological sciences, Canopy, Coefficient of determination, 010504 meteorology & atmospheric sciences, Sustainable forest management, UT-Hybrid-D, Height models, Management, Monitoring, Policy and Law, Atmospheric sciences, 010603 evolutionary biology, 01 natural sciences, ITC-HYBRID, Aboveground biomass change, Interferometric synthetic aperture radar, Tropical rainforest, Ecosystem, 0105 earth and related environmental sciences, Nature and Landscape Conservation, Biomass (ecology), Forestry, Interferometric synthetic aperture radar (InSAR) data, 15. Life on land, Above ground, 13. Climate action, Greenhouse gas, ITC-ISI-JOURNAL-ARTICLE, Environmental science, TanDEM-X

Abstract

The area-wide estimation of aboveground biomass (AGB) and its changes as a proxy for the sequestration and emission of carbon are currently associated with high uncertainties. Here we combined interferometric synthetic aperture radar (InSAR) height models derived from TanDEM-X with repeated ground-based inventories from the years 2012 and 2019 to estimate InSAR height and AGB changes in a structurally diverse and dynamic landscape in Sumatra, Indonesia. The results suggested that the InSAR height models were highly accurate and the relationship between InSAR height and AGB change resulted in a coefficient of determination R 2 of 0.65 and a cross-validated root mean square error (RMSE) of 2.38 Mg ha−1 year−1, equivalent to 13.32% of the actual AGB difference range. The estimated AGB changes with TanDEM-X were further related to the initial canopy height and fire activities in the study area. Initial canopy heights and the occurrences of fires had a significant effect on the AGB change. In general, low canopy heights tend to be associated with increasing AGB over time, whereas high canopy heights tend to be associated with stable or decreasing AGB. As expected, fires had a negative impact on the AGB changes being more pronounced in forest areas compared to oil palm concessions. The results of this study are relevant for the utilization of spaceborne InSAR height models and its potential to estimate canopy height and AGB change on large spatial scales. It was demonstrated that these changes can be related to their sources and ecosystem processes. This AGB change estimation technique can be used to model the impacts of fires on AGB change and carbon emissions, which are important for sustainable forest management.

Published

2021

41. Summer drought exposure, stand structure, and soil properties jointly control the growth of European beech along a steep precipitation gradient in northern Germany

Author

Robert Weigel, Banzragch Bat‐Enerel, Choimaa Dulamsuren, Lena Muffler, Greta Weithmann, and Christoph Leuschner

Subjects

Global and Planetary Change, Soil, Ecology, Germany, Climate Change, Fagus, Environmental Chemistry, Water, Seasons, Forests, General Environmental Science, Droughts, Trees

Abstract

Increasing exposure to climate warming-related drought and heat threatens forest vitality in many regions on earth, with the trees' vulnerability likely depending on local climatic aridity, recent climate trends, edaphic conditions, and the drought acclimatization and adaptation of populations. Studies exploring tree species' vulnerability to climate change often have a local focus or model the species' entire distribution range, which hampers the separation of climatic and edaphic drivers of drought and heat vulnerability. We compared recent radial growth trends and the sensitivity of growth to drought and heat in central populations of a widespread and naturally dominant tree species in Europe, European beech (Fagus sylvatica), at 30 forest sites across a steep precipitation gradient (500-850 mm yearDie zunehmende Gefährdung durch Trockenheit und Hitze im Zusammenhang mit der Klimaerwärmung bedroht die Vitalität der Wälder in vielen Regionen der Erde, wobei die Anfälligkeit der Bäume wahrscheinlich von der lokalen Aridität, den jüngsten Klimatrends, den edaphischen Bedingungen und der Trockenheitsakklimatisierung und -anpassung der Populationen abhängt. Studien, die sich mit der Anfälligkeit von Baumarten für den Klimawandel befassen, sind häufig lokal ausgerichtet oder modellieren das gesamte Verbreitungsgebiet der Art, was die Trennung der Bedeutung von klimatischen und edaphischen Faktoren für die Anfälligkeit für Trockenheit und Hitze erschwert. Wir haben die aktuellen radialen Wachstumstrends und die Trockenheits- und Hitzesensitivität in zentralen Populationen einer in Europa weit verbreiteten und von Natur aus dominanten Baumart, der Rotbuche (Fagus sylvatica), an 30 Waldstandorten über einen steilen Niederschlagsgradienten (500-850 mm pro Jahr) von kurzer geographischer Länge verglichen, um das Anpassungspotenzial der Art zu bewerten. Der größenstandardisierte Grundflächenzuwachs war während des Zeitraums der rasanten Klimaerwärmung seit den frühen 1980er Jahren in Populationen mit mehr als 360 mm Niederschlag in der Vegetationsperiode (April-September) konstanter, während die Trends an Standorten mit weniger als 360 mm Niederschlag deutlich negativer waren. Klimatische Trockenheit im Juni erwies sich als der einflussreichste Klimafaktor, der das radiale Wachstum beeinflusste, wobei die Auswirkungen an trockeneren Standorten stärker waren. Eine jahrzehntelange Verschlechterung der klimatischen Wasserbilanz des Sommers wurde als wichtigster Faktor identifiziert, der zu einem Wachstumsrückgang führt, der durch höhere Stammdichten noch verstärkt wird. Die interannuelle Wachstumsvariabilität hat seit Anfang der 1980er Jahre zugenommen, und die Variabilität ist an trockeneren und sandigeren Standorten generell höher. Auch die Synchronität des Wachstums innerhalb der Populationen ist an sandigeren Standorten höher und hat mit einer Abnahme der klimatischen Wasserbilanz im Juni zugenommen. Wir kommen zu dem Schluss, dass die Buche in letzter Zeit an trockeneren Standorten im Zentrum ihres Verbreitungsgebiets mit einem Wachstumsrückgang konfrontiert ist, der auf die mit dem Klimawandel verbundene Aridifizierung zurückzuführen ist. Unsere Ergebnisse warnen davor, die Trockenheitsanfälligkeit von Bäumen allein anhand von Klimaprojektionen vorherzusagen, da sich die Bodeneigenschaften als wichtiger Einflussfaktor erwiesen haben.

Published

2022

42. Influence of Root Diameter and Soil Depth on the Xylem Anatomy of Fine- to Medium-Sized Roots of Mature Beech Trees in the Top- and Subsoil

Author

Kristina Kirfel, Christoph Leuschner, Dietrich Hertel, and Bernhard Schuldt

Subjects

cambial aging, deep roots, Fagus sylvatica, hydraulic conductivity, high-conductivity roots, vascular differentiation, Plant culture, SB1-1110

Abstract

Despite their importance for water uptake and transport, the xylem anatomical and hydraulic properties of tree roots have only rarely been studied in the field. We measured mean vessel diameter (D), vessel density (VD), relative vessel lumen area (lumen area per xylem area) and derived potential hydraulic conductivity (Kp) in the xylem of 197 fine- to medium-diameter roots (1–10 mm) in the topsoil and subsoil (0–200 cm) of a mature European beech forest on sandy soil for examining the influence of root diameter and soil depth on xylem anatomical and derived hydraulic traits. All anatomical and functional traits showed strong dependence on root diameter and thus root age but no significant relation to soil depth. Averaged over topsoil and deep soil and variable flow path lengths in the roots, D increased linearly with root diameter from ∼50 μm in the smallest diameter class (1–2 mm) to ∼70 μm in 6–7 mm roots (corresponding to a mean root age of ∼12 years), but remained invariant in roots >7 mm. D never exceeded ∼82 μm in the 1–10 mm roots, probably in order to control the risk of frost- or drought-induced cavitation. This pattern was overlain by a high variability in xylem anatomy among similar-sized roots with Kp showing a higher variance component within than between root diameter classes. With 8% of the roots exceeding average Kp in their diameter class by 50–700%, we obtained evidence of the existence of ‘high-conductivity roots’ indicating functional differentiation among similar-sized roots. We conclude that the hydraulic properties of small to medium diameter roots of beech are mainly determined by root age, rendering root diameter a suitable predictor of hydraulic functioning, while soil depth – without referring to path length – had a negligible effect.

Published

2017

43. De novo transcriptome assembly and analysis of differential gene expression in response to drought in European beech.

Author

Markus Müller, Sarah Seifert, Torben Lübbe, Christoph Leuschner, and Reiner Finkeldey

Subjects

Medicine, Science

Abstract

Despite the ecological and economic importance of European beech (Fagus sylvatica L.) genomic resources of this species are still limited. This hampers an understanding of the molecular basis of adaptation to stress. Since beech will most likely be threatened by the consequences of climate change, an understanding of adaptive processes to climate change-related drought stress is of major importance. Here, we used RNA-seq to provide the first drought stress-related transcriptome of beech. In a drought stress trial with beech saplings, 50 samples were taken for RNA extraction at five points in time during a soil desiccation experiment. De novo transcriptome assembly and analysis of differential gene expression revealed 44,335 contigs, and 662 differentially expressed genes between the stress and normally watered control group. Gene expression was specific to the different time points, and only five genes were significantly differentially expressed between the stress and control group on all five sampling days. GO term enrichment showed that mostly genes involved in lipid- and homeostasis-related processes were upregulated, whereas genes involved in oxidative stress response were downregulated in the stressed seedlings. This study gives first insights into the genomic drought stress response of European beech, and provides new genetic resources for adaptation research in this species.

Published

2017

44. An interdisciplinary framework to describe and evaluate the functioning of forest ecosystems

Author

Peter Annighöfer, Stefan Scheu, Niko Balkenhol, Christian Ammer, Andreas Schuldt, Bernhard Schuldt, Andrea Polle, Christoph Leuschner, and Jonas Glatthorn

Subjects

0106 biological sciences, business.industry, media_common.quotation_subject, Environmental resource management, Ambiguity, 15. Life on land, 010603 evolutionary biology, 01 natural sciences, Terminology, ComputingMilieux_GENERAL, Goods and services, Conceptual blending, 13. Climate action, Forest ecology, Normative, Ecosystem, Sociology, business, Function (engineering), ComputingMilieux_MISCELLANEOUS, Ecology, Evolution, Behavior and Systematics, 010606 plant biology & botany, media_common

Abstract

Forest ecosystems are shaped by internal dynamics and external factors like forest management. A modified physical appearance of ecosystems may affect the short- and long-term provision of ecosystem goods and services (EG&S) from forests. Ecosystem functioning research provides powerful tools for both, the mechanistic description of ecosystem dynamics and the normative assessment of the value of ecosystems. Holistic insights into the functioning of ecosystems require interdisciplinary projects. However, disciplinary differences in terminology and implicit underlying assumptions about relationships between descriptive ecosystem characteristics and their relevance for society may lead to misunderstandings hindering conceptual integration of disciplines. This highlights the need for a common language in ecosystem functioning research. Here, we provide a classification scheme of different types of ecosystem characteristics applicable across disciplines. We introduce a terminology that unambiguously differentiates between normative and descriptive uses of the terms ‘ecosystem function’, ‘ecosystem functioning’ and ‘ecosystem goods and services’. Based on this terminology, we propose a framework facilitating the explicit communication of hypotheses, underlying assumptions, analyses and conclusions belonging to three different aspects of ecosystem functioning: (1) mechanistic ecosystem functioning, (2) supplying ecosystem functioning and (3) ecosystem integrity. ‘Mechanistic ecosystem functioning’ addresses relationships and interactions between purely descriptive ecosystem characteristics and their dependence on external factors. ‘Supplying ecosystem functioning’ translates descriptive ecosystem characteristics into benefits for society in providing EG&S. ‘Ecosystem integrity’ assesses the capabilities of ecosystems to provide EG&S in the long term. We further propose the use of a mathematical interpretation of the term ‘ecosystem function’ as ‘characteristic A is the function of characteristics B, C, …, X’. This definition clearly accounts for complex relationships between ecosystem characteristics and avoids ambiguity inherent in the discrimination of ‘ecosystem-functions’ and other (‘non-functional’) ecosystem characteristics. Our approach will increase understanding across disciplines and foster joint syntheses by providing a unified framework for interdisciplinary studies.

Published

2021

45. Vertical temperature and air humidity gradients in beech and oak forests, and the forest interior climate created by beech

Author

Christoph Leuschner, Stefan Hohnwald, Any Mary Petriţan, and Helge Walentowski

Subjects

Ecology, Plant Science, Ecology, Evolution, Behavior and Systematics

Published

2023

46. Climate implications on forest above- and belowground carbon allocation patterns along a tropical elevation gradient on Mt. Kilimanjaro (Tanzania)

Author

David Schellenberger Costa, Natalia Sierra Cornejo, Dietrich Hertel, Christoph Leuschner, Joscha N. Becker, and Andreas Hemp

Subjects

0106 biological sciences, 010504 meteorology & atmospheric sciences, Climate change, Forests, Biology, Tanzania, 010603 evolutionary biology, 01 natural sciences, Trees, Carbon cycle, Net primary production, Soil, Forest ecology, Fine roots, Biomass, Transect, Ecosystem, Ecology, Evolution, Behavior and Systematics, 0105 earth and related environmental sciences, Tropical Climate, Ecology, Tropical montane forest, Primary production, Ecosystem Ecology–Original Research, Plant litter, Carbon, Productivity (ecology), Africa, Litter

Abstract

Tropical forests represent the largest store of terrestrial biomass carbon (C) on earth and contribute over-proportionally to global terrestrial net primary productivity (NPP). How climate change is affecting NPP and C allocation to tree components in forests is not well understood. This is true for tropical forests, but particularly for African tropical forests. Studying forest ecosystems along elevation and related temperature and moisture gradients is one possible approach to address this question. However, the inclusion of belowground productivity data in such studies is scarce. On Mt. Kilimanjaro (Tanzania), we studied aboveground (wood increment, litter fall) and belowground (fine and coarse root) NPP along three elevation transects (c. 1800–3900 m a.s.l.) across four tropical montane forest types to derive C allocation to the major tree components. Total NPP declined continuously with elevation from 8.5 to 2.8 Mg C ha−1 year−1 due to significant decline in aboveground NPP, while fine root productivity (sequential coring approach) remained unvaried with around 2 Mg C ha−1 year−1, indicating a marked shift in C allocation to belowground components with elevation. The C and N fluxes to the soil via root litter were far more important than leaf litter inputs in the subalpine Erica forest. Thus, the shift of C allocation to belowground organs with elevation at Mt. Kilimanjaro and other tropical forests suggests increasing nitrogen limitation of aboveground tree growth at higher elevations. Our results show that studying fine root productivity is crucial to understand climate effects on the carbon cycle in tropical forests.

Published

2021

47. 60-year record of stem xylem anatomy and related hydraulic modification under increased summer drought in ring- and diffuse-porous temperate broad-leaved tree species

Author

Markus Hauck, Bernhard Schuldt, Jorma Zimmermann, Christoph Leuschner, and Roman M. Link

Subjects

Ecology, Physiology, Climate change, Xylem, Forestry, Plant Science, Anatomy, Broad-leaved tree, Water balance, Hydraulic conductivity, Temperate climate, Environmental science, Spatial variability, Precipitation

Abstract

Key message By combining dendrochronological time-series analysis with radial vessel features, we show that the reconstruction of hydraulic properties improves our understanding of tree species’ acclimation potential to climate change. Abstract The vascular architecture plays a crucial role in the productivity and drought tolerance of broadleaf trees, but it is not yet fully understood how the hydraulic system is acclimating to a warmer and drier climate. Because vessel features may record temporal and spatial variability in climatic signals of the past better than tree-ring width, we combined dendrochronological time-series analysis with the calculation of stem hydraulic properties derived from radial vessel features. We aimed to reconstruct the development and sensitivity of the hydraulic system over six decades and to identify climatic control of xylem anatomy for five co-existing broad-leaved diffuse- and ring-porous tree species (genera Acer, Fagus, Fraxinus and Quercus) across three sites covering a precipitation gradient from 548 to 793 mm. We observed a significant influence of the climatic water balance (CWB) on the vessel features of all species, but the time lag, magnitude and direction of the response was highly species-specific. All diffuse-porous species suffered a decline in vessel diameter in dry years, and increase in vessel density in dry years and the year following. However, F. sylvatica was the only species with a significant long-term change in anatomical traits and a significant reduction in potential hydraulic conductivity (Kp) after dry winters and in dry summers, accompanied with the largest long-term decline in tree-ring width and the largest growth reduction in and after years with a more negative CWB. In contrast, the comparison across the precipitation gradient did not reveal any significant vessel-climate relationships. Our results revealed considerable plasticity in the hydraulic system especially of F. sylvatica, but also evidence of the drought-sensitivity of this species in accordance with earlier dendroecological and physiological studies. We conclude that the long-term reconstruction of hydraulic properties can add substantially to the understanding of the acclimation potential of different tree species to climate change.

Published

2021

48. Elevational trends of tree fine root traits in species‐rich tropical Andean forests

Author

Kerstin Pierick, Roman M. Link, Christoph Leuschner, and Jürgen Homeier

Subjects

Ecology, Evolution, Behavior and Systematics

Published

2022

49. Consequences of tropical rainforest conversion to tree plantations on fine root dynamics and functional traits

Author

Martyna M. Kotowska, Sasya Samhita, Dietrich Hertel, Triadiati Triadiati, Friderike Beyer, Kara Allen, Roman M. Link, and Christoph Leuschner

Subjects

Ecology, Evolution, Behavior and Systematics

Published

2022

50. Fine root productivity and turnover of ectomycorrhizal and arbuscular mycorrhizaltree species in a temperate broad-leaved mixed forest

Author

Petra Kubisch, Dietrich Hertel, and Christoph Leuschner

Subjects

Acer, Fagus, Fraxinus, Tilia, Carpinus, Root branching order, Plant culture, SB1-1110

Abstract

Advancing our understanding of tree fine root dynamics is of high importance for tree physiology and forest biogeochemistry. In temperate broad-leaved forests, ectomycorrhizal (EM) and arbuscular mycorrhizal (AM) tree species often are coexisting. It is not known whether EM and AM trees differ systematically in fine root dynamics and belowground resource foraging strategies. We measured fine root productivity (FRP) and fine root turnover (and its inverse, root longevity) of three EM and three AM broad-leaved tree species in a natural cool-temperate mixed forest using ingrowth cores and combined the productivity data with data on root biomass per root orders. FRP and root turnover were related to root morphological traits and aboveground productivity.FRP differed up to twofold among the six coexisting species with larger species differences in lower horizons than in the topsoil. Root turnover varied up to fivefold among the species with lowest values in Acer pseudoplatanus and highest in its congener A. platanoides. Variation in root turnover was larger within the two groups than between EM and AM species. We conclude that the main determinant of fine root productivity and turnover in this mixed forest is species identity, while the influence of mycorrhiza type seems to be less important.

Published

2016