Longer Growing Seasons Cause Hydrological Regime Shifts in Central European Forests

Kupec, Petr; Deutscher, Jan; Futter, Martyn N.

doi:10.3390/f12121656

Cited by 12 publications

(7 citation statements)

References 71 publications

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“…Hydrological disciplines in which tipping points have been identified include surface runoff (Dijkstra et al, 2019;Dunne and Black, 1970a;Horton, 1945), groundwater (Bailey, 2011;Figura et al, 2011), hydrometeorology (Buitink et al, 2020;Denissen et al, 2020;Krishnamurthy R et al, 2020), ecohydrology (Hirota et al, 2011;Mayor et al, 2019), and water quality (Dakos et al, 2019;Dijkstra et al, 2019). Moreover, these tipping points manifest themselves in all places: from arctic (Devoie et al, 2019;Rosier et al, 2021) to temperate climates (Kupec et al, 2021;van der Velde et al, 2021), from wet 10 (Loverde- Oliveira et al, 2009;Verbesselt et al, 2016) to arid regions (Bailey, 2011;Bernardino et al, 2020), and from hydrological source (Marty, 2008) to sink (Kirwan and Megonigal, 2013).…”

Section: Tipping Points and Thresholds In Hydrologymentioning

confidence: 99%

Where should hydrology go? An early-career perspective on the next IAHS Scientific Decade: 2023-2032

Hateren¹,

Jongen²,

Al-Zawaidah³

et al. 2022

Preprint

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This paper shares an Early-Career Scientist (ECS) perspective on potential themes for the upcoming International Association of Hydrological Sciences (IAHS) scientific decade (SD). Six discussion sessions were organised in four countries in western Europe in spring 2022. Early-career hydrologists were invited to join the sessions to formulate potential SD themes, to provide feedback on themes proposed in earlier sessions, and to further develop the proposed themes. This community paper summarizes the outcome of these discussion sessions, where three potential themes were identified that could serve to direct the broader hydrological community: “Tipping points and thresholds in hydrology”, “Intensification of the water cycle”, and “Water services under pressure”. Additionally, four trends were distinguished concerning the way in which hydrological research is conducted: big data, bridging science and practice, open science, and inter- and multidisciplinarity. These themes and trends can provide valuable input for future discussions on the theme for the next IAHS SD and they can also serve as a guidance for future research pathways.

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Section: Tipping Points and Thresholds In Hydrologymentioning

confidence: 99%

Where should hydrology go? An early-career perspective on the next IAHS Scientific Decade: 2023-2032

Hateren¹,

Jongen²,

Al-Zawaidah³

et al. 2022

Preprint

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“…Climate change can alter not only precipitation patterns, temperature regimes, the timing of snowmelt, and vegetation zones but also the length of the growing season [12]. These alterations have significant implications for evapotranspiration, which subsequently affects the quantity and distribution of groundwater recharge.…”

Section: Introductionmentioning

confidence: 99%

“…This endeavour involves a range of ecological, hydrological, and climatic elements. Understanding these factors is necessary for the effective management of land and water resources in both types of ecosystems [12]. In reaction to the shortcomings listed above and the specific local conditions of the study site, this paper intends to test the performance of an adaptation of the White method, which is described in the methodological section, under a nonstationary hydrological regime caused by the continuous declining trend of groundwater levels in the pilot region.…”

Section: Introductionmentioning

confidence: 99%

Groundwater Recharge from Below under Changing Hydro-Meteorological Conditions in a Forested and Grassland Site of the Great Hungarian Plain

Szabó,

Gribovszki,

Szolgay

et al. 2023

Forests

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The process of groundwater evapotranspiration and its subsequent recharge are fundamental aspects of the Earth’s natural water cycle and have significant implications for the preservation and functionality of various forested ecosystems. This study presents a case analysis examining the recent fluctuations in groundwater levels and their replenishment in two wells situated at a designated forested experimental area and a control site. The magnitude and temporal fluctuations of groundwater recharge were examined through the utilisation of a novel adaptation of the traditional White method, which was specifically tailored to the local context. We also tested the sensitivity of the White method as an indicator of the system’s behaviour because the signal has changed in relation to the access of the forests to groundwater under the conditions of regionally declining groundwater resources and a warming climate. The novelty of this approach is found in the examination of the temporal fluctuations in groundwater recharge, which are influenced by both a decrease in groundwater levels caused by forest evaporation in response to climate change and a regional reduction in groundwater supplies. As a result, the ongoing decrease in groundwater levels may have significant adverse effects on local forests.

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“…Clearly, the dominant vegetation type (e.g., forest or heathland) is an important factor. Physiologic controls on carbon allocation (Cabon et al 2022 ), resilience to drought (Kupec et al 2021 ) and inherent growth rates all vary across tree species and varieties. The dominant vegetation type cannot be considered in isolation.…”

Section: The Terrestrial Carbon Sink: What How and Whymentioning

confidence: 99%

Leveraging research infrastructure co-location to evaluate constraints on terrestrial carbon cycling in northern European forests

Futter,

Dirnböck,

Forsius

et al. 2023

Ambio

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Integrated long-term, in-situ observations are needed to document ongoing environmental change, to “ground-truth” remote sensing and model outputs and to predict future Earth system behaviour. The scientific and societal value of in-situ observations increases with site representativeness, temporal duration, number of parameters measured and comparability within and across sites. Research Infrastructures (RIs) can support harmonised, cross-site data collection, curation and publication. Integrating RI networks through site co-location and standardised observation methods can help answers three questions about the terrestrial carbon sink: (i) What are present and future carbon sequestration rates in northern European forests? (ii) How are these rates controlled? (iii) Why do the observed patterns exist? Here, we present a conceptual model for RI co-location and highlight potential insights into the terrestrial carbon sink achievable when long-term in-situ Earth observation sites participate in multiple RI networks (e.g., ICOS and eLTER). Finally, we offer recommendations to promote RI co-location.

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Longer Growing Seasons Cause Hydrological Regime Shifts in Central European Forests

Cited by 12 publications

References 71 publications

Where should hydrology go? An early-career perspective on the next IAHS Scientific Decade: 2023-2032

Where should hydrology go? An early-career perspective on the next IAHS Scientific Decade: 2023-2032

Groundwater Recharge from Below under Changing Hydro-Meteorological Conditions in a Forested and Grassland Site of the Great Hungarian Plain

Leveraging research infrastructure co-location to evaluate constraints on terrestrial carbon cycling in northern European forests

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