| 1. |
- Buendía, Corina, et al.
(author)
-
Evaluating the effect of nutrient redistribution by animals on the phosphorus cycle of lowland Amazonia
- 2018
-
In: Biogeosciences. - : Copernicus GmbH. - 1726-4170 .- 1726-4189. ; 15:1, s. 279-295
-
Journal article (peer-reviewed)abstract
- Phosphorus (P) availability decreases with soil age and potentially limits the productivity of ecosystems growing on old and weathered soils. Despite growing on ancient soils, ecosystems of lowland Amazonia are highly productive and are among the most biodiverse on Earth. P eroded and weathered in the Andes is transported by the rivers and deposited in floodplains of the lowland Amazon basin creating hotspots of P fertility. We hypothesize that animals feeding on vegetation and detritus in these hotspots may redistribute P to P-depleted areas, thus contributing to dissipate the P gradient across the landscape. Using a mathematical model, we show that animal-driven spatial redistribution of P from rivers to land and from seasonally flooded to terra firme (upland) ecosystems may sustain the P cycle of Amazonian lowlands. Our results show how P imported to land by terrestrial piscivores in combination with spatial redistribution of herbivores and detritivores can significantly enhance the P content in terra firme ecosystems, thereby highlighting the importance of food webs for the biogeochemical cycling of Amazonia.
|
|
| 2. |
|
|
| 3. |
- Porada, Philipp, et al.
(author)
-
Estimating global nitrous oxide emissions by lichens and bryophytes with a process-based productivity model
- 2017
-
In: Biogeosciences. - : Copernicus GmbH. - 1726-4170 .- 1726-4189. ; 14:6, s. 1593-1602
-
Journal article (peer-reviewed)abstract
- Nitrous oxide is a strong greenhouse gas and atmospheric ozone-depleting agent which is largely emitted by soils. Recently, lichens and bryophytes have also been shown to release significant amounts of nitrous oxide. This finding relies on ecosystem-scale estimates of net primary productivity of lichens and bryophytes, which are converted to nitrous oxide emissions by empirical relationships between productivity and respiration, as well as between respiration and nitrous oxide release. Here we obtain an alternative estimate of nitrous oxide emissions which is based on a global process-based non-vascular vegetation model of lichens and bryophytes. The model quantifies photosynthesis and respiration of lichens and bryophytes directly as a function of environmental conditions, such as light and temperature. Nitrous oxide emissions are then derived from simulated respiration assuming a fixed relationship between the two fluxes. This approach yields a global estimate of 0.27 (0.19-0.35) (TgN(2)O) year(-1) released by lichens and bryophytes. This is lower than previous estimates but corresponds to about 50% of the atmospheric deposition of nitrous oxide into the oceans or 25% of the atmospheric deposition on land. Uncertainty in our simulated estimate results from large variation in emission rates due to both physiological differences between species and spatial heterogeneity of climatic conditions. To constrain our predictions, combined online gas exchange measurements of respiration and nitrous oxide emissions may be helpful.
|
|
| 4. |
- Porada, Philipp, et al.
(author)
-
Significant contribution of non-vascular vegetation to global rainfall interception
- 2018
-
In: Nature Geoscience. - : Springer Science and Business Media LLC. - 1752-0894 .- 1752-0908. ; 11:8, s. 563-
-
Journal article (peer-reviewed)abstract
- Non-vascular vegetation has been shown to capture considerable quantities of rainfall, which may affect the hydrological cycle and climate at continental scales. However, direct measurements of rainfall interception by non-vascular vegetation are confined to the local scale, which makes extrapolation to the global effects difficult. Here we use a process-based numerical simulation model to show that non-vascular vegetation contributes substantially to global rainfall interception. Inferred average global water storage capacity including non-vascular vegetation was 2.7 mm, which is consistent with field observations and markedly exceeds the values used in land surface models, which average around 0.4 mm. Consequently, we find that the total evaporation of free water from the forest canopy and soil surface increases by 61% when non-vascular vegetation is included, resulting in a global rainfall interception flux that is 22% of the terrestrial evaporative flux (compared with only 12% for simulations where interception excludes non-vascular vegetation). We thus conclude that non-vascular vegetation is likely to significantly influence global rainfall interception and evaporation with consequences for regional-to continental-scale hydrologic cycling and climate.
|
|
| 5. |
- Singh, Chandrakant, 1992-
(author)
-
Rooting for forest resilience : Implications of climate and land-use change on the tropical rainforests
- 2023
-
Doctoral thesis (other academic/artistic)abstract
- Tropical rainforests in the Amazon and Congo River basins and their climate are mutually dependent. Evaporation from these forests help regulate the regional and global water cycle. Furthermore, these rainforests themselves depend on precipitation to sustain their structure and functions. However, the rapid increase in human activities (such as burning fossil fuels and deforestation) has significantly changed the rainforests’ climate. Due to the effect of human-induced perturbations on moisture feedbacks (i.e., precipitation and evaporation patterns), these rainforests risk tipping to a savanna or treeless state.Understanding how these forests respond to climate change will aid in assessing their resilience to water-induced perturbations as well as in anticipating and preparing for potential tipping risks in the future. However, our understanding of how vegetation responds to climate change is fragmented, which limits our capacity to predict these risks. Previous studies have primarily relied on precipitation data to understand these forest-to-savanna transitions. However, ecosystem transition risks are also associated with water-stress, which depends on the vegetation’s capacity to adapt to drier conditions by storing water in its root zone. This thesis investigates the effect of hydroclimatic changes on root zone adaptation and its implications for forest resilience.Paper I uses remote sensing data to analyse water-stress and drought coping strategies across the rainforest-savanna transects. Paper II uses the root zone storage capacity to quantify the resilience of forest ecosystems. Using the empirical understanding of root zone forest dynamics and hydroclimatic estimates from Earth System Models, Paper III projects future forest transitions and estimates tipping risks by the end of the 21st century under four different shared socio-economic pathways. Paper IV uses atmospheric moisture tracking data to investigate the leverage landholders in South America have over precipitation and the resilience of forest ecosystems. Papers I and II reveal the non-linear relationship between the ecosystem’s above-ground structure and root zone storage capacity. These studies indicate that, under hydroclimatic changes, the ecosystem’s root zone storage capacity is much more dynamic than its above-ground forest structure and is more representative of the ecosystem’s transient state than precipitation. Ignoring this root zone adaptive capacity can underestimate forest resilience, primarily observed in the Congo rainforest. Paper III projects that the risk of forest-savanna transition will increase with climate change severity, most prominently observed in the Amazon rainforest. Paper IV finds that all landholders have equal leverage over the moisture precipitating locally and over farther-downwind land systems. According to this study, smallholders have a disproportionately larger influence over forest rainfall. However, large landholders have a larger influence on forest resilience as well as over the moisture precipitating on croplands and pastures. These results warrant the need for policies to factor in the impact of deforestation on downwind actors and promote effective ecosystem stewardship. The insights from this thesis highlight the importance of understanding and assessing ecosystem dynamics under a rapidly changing climate for strengthening management and conservation efforts across the globe.
|
|
| 6. |
- Thurner, Martin, et al.
(author)
-
Evaluation of climate-related carbon turnover processes in global vegetation models for boreal and temperate forests
- 2017
-
In: Global Change Biology. - : Wiley. - 1354-1013 .- 1365-2486. ; 23:8, s. 3076-3091
-
Journal article (peer-reviewed)abstract
- Turnover concepts in state-of-the-art global vegetation models (GVMs) account for various processes, but are often highly simplified and may not include an adequate representation of the dominant processes that shape vegetation carbon turnover rates in real forest ecosystems at a large spatial scale. Here, we evaluate vegetation carbon turnover processes in GVMs participating in the Inter-Sectoral Impact Model Intercomparison Project (ISI-MIP, including HYBRID4, JeDi, JULES, LPJml, ORCHIDEE, SDGVM, and VISIT) using estimates of vegetation carbon turnover rate (k) derived from a combination of remote sensing based products of biomass and net primary production (NPP). We find that current model limitations lead to considerable biases in the simulated biomass and in k (severe underestimations by all models except JeDi and VISIT compared to observation-based average k), likely contributing to underestimation of positive feedbacks of the northern forest carbon balance to climate change caused by changes in forest mortality. A need for improved turnover concepts related to frost damage, drought, and insect outbreaks to better reproduce observation-based spatial patterns in k is identified. As direct frost damage effects on mortality are usually not accounted for in these GVMs, simulated relationships between k and winter length in boreal forests are not consistent between different regions and strongly biased compared to the observation-based relationships. Some models show a response of k to drought in temperate forests as a result of impacts of water availability on NPP, growth efficiency or carbon balance dependent mortality as well as soil or litter moisture effects on leaf turnover or fire. However, further direct drought effects such as carbon starvation (only in HYBRID4) or hydraulic failure are usually not taken into account by the investigated GVMs. While they are considered dominant large-scale mortality agents, mortality mechanisms related to insects and pathogens are not explicitly treated in these models.
|
|
