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Spatially distributed tracer-aided runoff modelling and dynamics of storage and water ages in a permafrost-influenced catchment (2019)

Piovano, Thea I. [Verfasser] ; Tetzlaff, Doerthe [Verfasser] ; Carey, Sean K. [Verfasser] ; [et al.]

Berlin : Humboldt-Universität zu Berlin

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UID:

b3kat_BV045910230

Format: 1 Online-Ressource

Language: English

DOI: 10.18452/20607

URN: urn:nbn:de:kobv:11-110-18452/21386-3

URL: Volltext (kostenfrei)

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Water ages in the critical zone of long-term experimental sites in northern latitudes (2018)

Sprenger, Matthias [Sonstige] ; Tetzlaff, Doerthe [Sonstige] ; Buttle, Jim [Sonstige] ; [et al.]

Berlin : Humboldt-Universität zu Berlin

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UID:

b3kat_BV045137037

Format: 1 Online-Ressource

Language: English

DOI: 10.18452/19632

URN: urn:nbn:de:kobv:11-110-18452/20406-7

URL: Volltext (kostenfrei)

Author information: Sprenger, Matthias

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3

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Critical Zone Storage Controls on the Water Ages of Ecohydrological Outputs (2020)

Kuppel, Sylvain ; Tetzlaff, Doerthe ; Maneta, Marco P. ; [et al.]

Berlin : Humboldt-Universität zu Berlin

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UID:

edochu_18452_23529

Format: 1 Online-Ressource (11 Seiten)

Content: Spatially explicit knowledge of the origins of water resources for ecosystems and rivers is challenging when using tracer data alone. We use simulations from a spatially distributed model calibrated by extensive ecohydrological data sets in a small, energy‐limited catchment, where hillslope‐riparian dynamics are broadly representative of humid boreal headwater catchments that are experiencing rapid environmental transition. We hypothesize that in addition to wetness status, landscape heterogeneity modulates the water pathways that sustain ecosystem function and streamflows. Simulations show that catchment storage inversely controls stream water ages year‐round, but only during the drier seasons for transpiration and soil evaporation. The ages of these evaporative outputs depend much less on wetness status in the oft‐saturated riparian soils than on the freely draining hillslopes that subsidize them. This work highlights the need to consider local dynamics and time‐changing lateral heterogeneities when interpreting the ages, and thus the vulnerability, of water resources feeding streams and ecosystems in landscapes.

Content: Knowing how much time water spends in a landscape (its “age”) helps understanding how water travels through it. These dynamics inform of the stability of water resources for ecosystems and societies, and of their vulnerabilities under climate and land use changes. Water ages may vary depending on how wet or dry a location gets between seasons and years. We thus need to learn more about the demographics (“how much and how old?”) of the water used by plants, evaporated from soils, and flowing in streams, but it is often impossible to monitor the heterogeneity of water pathways within landscapes. Addressing this challenge, we used a numerical model built upon coupling ecohydrological processes and that maps landscape locations. We adjusted this model using multiple data sets in a catchment representative of humid boreal environments where climate and vegetation are rapidly changing. We found markedly different aging patterns between water escaping the system through the plants, soils, and stream, depending on water storage status. This changing duration of water movement also differs between the catchment as a whole and its parts. This method can be used to better understand the multiple ways in which water moves through landscapes, in current and future conditions.

Content: Peer Reviewed

In: Hoboken, NJ : Wiley, 47,16

Language: English

DOI: 10.1029/2020GL088897

DOI: 10.18452/22856

URN: urn:nbn:de:kobv:11-110-18452/23529-1

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4

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Visualizing catchment‐scale spatio‐temporal dynamics of storage‐flux‐age interactions using a tracer‐aided ecohydrological model (2022)

Smith, Aaron ; Tetzlaff, Doerthe ; Maneta, Marco P. ; [et al.]

Berlin : Humboldt-Universität zu Berlin

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UID:

edochu_18452_25263

Format: 1 Online-Ressource (3 Seiten)

ISSN: 0885-6087 , 0885-6087

Content: Peer Reviewed

In: New York, NY : Wiley, 36,2, 0885-6087

Language: English

DOI: 10.1002/hyp.14460

DOI: 10.18452/24586

URN: urn:nbn:de:kobv:11-110-18452/25263-1

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Estimates of water partitioning in complex urban landscapes with isotope‐aided ecohydrological modelling (2022)

Gillefalk, Mikael ; Tetzlaff, Doerthe ; Marx, Christian ; [et al.]

Berlin : Humboldt-Universität zu Berlin

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UID:

edochu_18452_25629

Format: 1 Online-Ressource (10 Seiten)

Content: Urban green space is increasingly viewed as essential infrastructure to build resilience to climate change by retaining water in the city landscape and balancing ecohydrological partitioning into evapotranspiration for cooling and groundwater recharge. Quantifying how different vegetation types affect water partitioning is essential for future management, but paucity of data and the complex heterogeneity of urban areas make water balance estimates challenging. Here, we provide a preliminary assessment of water partitioning from different sized patches of trees and grass as well as from sealed surfaces. To do this, we used limited field observations together with an advanced, process-based tracer-aided ecohydrological model at a meso-scale (5 km2) in central Berlin, Germany. Transpiration was the dominant green water flux accounting for over 50% of evapotranspiration in the modelled area. Green water fluxes were in general greater from trees compared with grass, but grass in large parks transpired more water compared with grass in small parks that were intensively used for recreation. Interception evaporation was larger for trees compared with grass, but soil water evaporation was greater for grass compared with trees. We also show that evapotranspiration from tree-covered areas comprise almost 80% of the total evapotranspiration from the whole model domain while making up less than 30% of the surface cover. The results form an important stepping-stone towards further upscaling over larger areas and highlights the importance of continuous high-resolution hydrological measurements in the urban landscape, as well as the need for improvements to ecohydrological models to capture important urban processes.

Content: Peer Reviewed

In: New York, NY : Wiley, 36,3

Language: English

DOI: 10.1002/hyp.14532

DOI: 10.18452/24948

URN: urn:nbn:de:kobv:11-110-18452/25629-8

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6

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Stable isotopes of water reveal differences in plant – soil water relationships across northern environments (2020)

Tetzlaff, Doerthe ; Buttle, James ; Carey, Sean ; [et al.]

Berlin : Humboldt-Universität zu Berlin

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UID:

edochu_18452_23614

Format: 1 Online-Ressource (19 Seiten)

ISSN: 0885-6087 , 0885-6087

Content: We compared stable isotopes of water in plant stem (xylem) water and soil collected over a complete growing season from five well-known long-term study sites in northern/cold regions. These spanned a decreasing temperature gradient from Bruntland Burn (Scotland), Dorset (Canadian Shield), Dry Creek (USA), Krycklan (Sweden), to Wolf Creek (northern Canada). Xylem water was isotopically depleted compared to soil waters, most notably for deuterium. The degree to which potential soil water sources could explain the isotopic composition of xylem water was assessed quantitatively using overlapping polygons to enclose respective data sets when plotted in dual isotope space. At most sites isotopes in xylem water from angiosperms showed a strong overlap with soil water; this was not the case for gymnosperms. In most cases, xylem water composition on a given sampling day could be better explained if soil water composition was considered over longer antecedent periods spanning many months. Xylem water at most sites was usually most dissimilar to soil water in drier summer months, although sites differed in the sequence of change. Open questions remain on why a significant proportion of isotopically depleted water in plant xylem cannot be explained by soil water sources, particularly for gymnosperms. It is recommended that future research focuses on the potential for fractionation to affect water uptake at the soil-root interface, both through effects of exchange between the vapour and liquid phases of soil water and the effects of mycorrhizal interactions. Additionally, in cold regions, evaporation and diffusion of xylem water in winter may be an important process.

Content: Peer Reviewed

In: New York, NY : Wiley, 35,1, 0885-6087

Language: English

DOI: 10.1002/hyp.14023

DOI: 10.18452/22939

URN: urn:nbn:de:kobv:11-110-18452/23614-9

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7

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Identifying Dominant Processes in Time and Space: Time‐Varying Spatial Sensitivity Analysis for a Grid‐Based Nitrate Model (2022)

Wu, Songjun ; Tetzlaff, Doerthe ; Yang, Xiaoqiang ; [et al.]

Berlin : Humboldt-Universität zu Berlin

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UID:

edochu_18452_26458

Format: 1 Online-Ressource (23 Seiten)

Content: Distributed models have been increasingly applied at finer spatiotemporal resolution. However, most diagnostic analyses aggregate performance measures in space or time, which might bias subsequent inferences. Accordingly, this study explores an approach for quantifying the parameter sensitivity in a spatiotemporally explicit way. We applied the Morris method to screen key parameters within four different sampling spaces in a grid‐based model (mHM‐Nitrate) for NO3‐N simulation in a mixed landuse catchment using a 1‐year moving window for each grid. The results showed that an overly wide range of aquatic denitrification rates could mask the sensitivity of the other parameters, leading to their spatial patterns only related to the proximity to outlet. With adjusted parameter space, spatial sensitivity patterns were determined by NO3‐N inputs and hydrological transport capacity, while temporal dynamics were regulated by annual wetness conditions. The relative proportion of parameter sensitivity further indicated the shifts in dominant hydrological/NO3‐N processes between wet and dry years. By identifying not only which parameter(s) is(are) influential, but where and when such influences occur, spatial sensitivity analysis can help evaluate current model parameterization. Given the marked sensitivity in agricultural areas, we suggest that the current NO3‐N parameterization scheme (land use‐dependent) could be further disentangled in these regions (e.g., into croplands with different rotation strategies) but aggregated in non‐agricultural areas; while hydrological parameterization could be resolved into a finer level (from spatially constant to land use‐dependent especially in nutrient‐rich regions). The spatiotemporal sensitivity pattern also highlights NO3‐N transport within soil layers as a focus for future model development.

Content: Peer Reviewed

In: [New York] : Wiley, 58,8

Language: English

DOI: 10.1029/2021WR031149

DOI: 10.18452/25789

URN: urn:nbn:de:kobv:11-110-18452/26458-1

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8

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Upscaling Tracer‐Aided Ecohydrological Modeling to Larger Catchments: Implications for Process Representation and Heterogeneity in Landscape Organization (2023)

Yang, Xiaoqiang ; Tetzlaff, Doerthe ; Müller, Christin ; [et al.]

Berlin : Humboldt-Universität zu Berlin

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UID:

edochu_18452_27097

Format: 1 Online-Ressource (22 Seiten)

Content: Stable isotopes of water are ideal tracers to integrate into process‐based models, advancing ecohydrological understanding. Current tracer‐aided ecohydrological modeling is mostly conducted in relatively small‐scale catchments, due to limited tracer data availability and often highly damped stream isotope signals in larger catchments (〉100 km2). Recent model developments have prioritized better spatial representation, offering new potential for advancing upscaling in tracer‐aided modeling. Here, we adapted the fully distributed EcH2O‐iso model to the Selke catchment (456 km2, Germany), incorporating monthly sampled isotopes from seven sites between 2012 and 2017. Parameter sensitivity analysis indicated that the information content of isotope data was generally complementary to discharge and more sensitive to runoff partitioning, soil water and energy dynamics. Multi‐criteria calibrations revealed that inclusion of isotopes could significantly improve discharge performance during validations and isotope simulations, resulting in more reasonable estimates of the seasonality of stream water ages. However, capturing isotopic signals of highly non‐linear near‐surface processes remained challenging for the upscaled model, but still allowed for plausible simulation of water ages reflecting non‐stationarity in transport and mixing. The detailed modeling also helped unravel spatio‐temporally varying patterns of water storage‐flux‐age interactions and their interplay under severe drought conditions. Embracing the upscaling challenges, this study demonstrated that even coarsely sampled isotope data can be of value in aiding ecohydrological modeling and consequent process representation in larger catchments. The derived innovative insights into ecohydrological functioning at scales commensurate with management decision making, are of particular importance for guiding science‐based measures for tackling environmental changes.

Content: Peer Reviewed

In: [New York] : Wiley, 59,3

Language: English

DOI: 10.1029/2022WR033033

DOI: 10.18452/26416

URN: urn:nbn:de:kobv:11-110-18452/27097-5

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Using water stable isotopes to understand evaporation, moisture stress, and re-wetting in catchment forest and grassland soils of the summer drought of 2018 (2020)

Kleine, Lukas ; Tetzlaff, Doerthe ; Smith, Aaron ; [et al.]

Berlin : Humboldt-Universität zu Berlin

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UID:

edochu_18452_22559

Format: 1 Online-Ressource (16 Seiten)

Content: In drought-sensitive lowland catchments, ecohydrological feedbacks to climatic anomalies can give valuable insights into ecosystem functioning in the context of alarming climate change projections. However, the dynamic influences of vegetation on spatio-temporal processes in water cycling in the critical zone of catchments are not yet fully understood. We used water stable isotopes to investigate the impacts of the 2018 drought on dominant soil–vegetation units of the mixed land use Demnitz Millcreek (DMC, north-eastern Germany) catchment (66 km2). The isotope sampling was carried out in conjunction with hydroclimatic, soil, groundwater, and vegetation monitoring. Drying soils, falling groundwater levels, cessation of streamflow, and reduced crop yields demonstrated the failure of catchment water storage to support “blue” (groundwater recharge and stream discharge) and “green” (evapotranspiration) water fluxes. We further conducted monthly bulk soil water isotope sampling to assess the spatio-temporal dynamics of water soil storage under forest and grassland vegetation. Forest soils were drier than the grassland, mainly due to higher interception and transpiration losses. However, the forest soils also had more freely draining shallow layers and were dominated by rapid young (age 〈2 months) water fluxes after rainfall events. The grassland soils were more retentive and dominated by older water (age 〉2 months), though the lack of deep percolation produced water ages 〉1 year under forest. We found the displacement of any “drought signal” within the soil profile limited to the isotopic signatures and no displacement or “memory effect” in d-excess over the monthly time step, indicating rapid mixing of new rainfall. Our findings suggest that contrasting soil–vegetation communities have distinct impacts on ecohydrological partitioning and water ages in the sub-surface. Such insights will be invaluable for developing sustainable land management strategies appropriate to water availability and building resilience to climate change.

Content: Peer Reviewed

Note: This article was supported by the German Research Foundation (DFG) and the Open Access Publication Fund of Humboldt-Universität zu Berlin.

In: Göttingen : Copernicus Publ., 24, Seiten 3737-3752

Language: English

DOI: 10.18452/21841

DOI: 10.5194/hess-24-3737-2020

URN: urn:nbn:de:kobv:11-110-18452/22559-3

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Critical Zone Response Times and Water Age Relationships Under Variable Catchment Wetness States: Insights Using a Tracer‐Aided Ecohydrological Model (2022)

Smith, Aaron ; Tetzlaff, Doerthe ; Maneta, Marco ; [et al.]

Berlin : Humboldt-Universität zu Berlin

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UID:

edochu_18452_25535

Format: 1 Online-Ressource (21 Seiten)

Content: The dynamic relationships between water flux and storage, together with the associated water ages and speed of hydrological responses (as proxies for velocity and celerity respectively) are fundamental to understanding how catchments react to hydroclimate perturbations, such as floods and droughts. Using results from a calibrated, tracer-aided ecohydrological model (EcH2O-iso) we analyzed the dynamics of storage-flux-age-response time (RT) interactions at scales that resolve the internal heterogeneity of these non-stationary relationships. EcH2O-iso has previously shown an adequate representation of ecohydrological flux partitioning and storage dynamics (celerity), and water ages (velocity) over 11-year at Demnitzer Millcreek catchment (DMC, 66 km2), a drought-sensitive, lowland catchment in Germany. The 11-year period had marked hydroclimatic contrasts facilitating the evaluation of flux-storage-age-RT dynamics under different wetness anomalies. Our results show that the spatio–temporal variability of soil moisture and ecohydrological partitioning dynamics reflect both land use (especially forest cover) and distinct soil units (i.e., brown earth vs. podzolic soils). Spatial differences in RTs of storage were driven by rapid soil evaporation and transpiration responses to rainfall, which revealed a divergence of transpiration ages from RTs. RTs of groundwater and streamflow were fast (days), but mediation by soil water storage dynamics caused marked separation from water ages (years-decades) of deeper flow paths. Analysis of RTs and ages revealed a degradation of process representation with coarsening model spatial resolution. This study uses novel analysis of the spatio-temporal interactions of flux-storage-age-RT from a model to understand the sensitivity and resilience of catchment functionality to hydroclimatic perturbations.

Content: Peer Reviewed

In: New York : Wiley, 58,4

Language: English

DOI: 10.1029/2021WR030584

DOI: 10.18452/24860

URN: urn:nbn:de:kobv:11-110-18452/25535-2

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