Same soil, different climate: Crop model intercomparison on translocated lysimeters

Groh, Jannis; Diamantopoulos, Efstathios; Duan, Xinbin; Ewert, Frank; Heinlein, Florian; Herbst, Michael; Holbak, Maja; Kamali, Bahareh; Kersebaum, Kurt Christian; Nendel, Claas; Priesack, Eckart; Steidl, Jörg; Sommer, Michael; Pütz, Thomas; Vanderborght, Jan; Vereecken, Harry; Wallor, Evelyn; Weber, Tobias; Wegehenkel, Martin; Weihermüller, Lutz; Gerke, Horst H.

doi:10.1002/vzj2.20202

Cited by 8 publications

(5 citation statements)

References 118 publications

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“…In our analysis, we focus solely on the relative changes in future mean yields and have not conducted historical simulations for model validation. While previous studies have demonstrated the reliability of PCSE (WOFOST) in crop yield simulations (Asseng et al., 2019; Gaso et al., 2021; Groh et al., 2022; Müller et al., 2021), its validation in NEC has not been performed to date. Furthermore, the potential impact of new pest and disease distributions resulting from climate change is qualitatively understood but has not been incorporated into any models, leading to an overly optimistic assessment (Tubiello et al., 2007).…”

Section: Discussionmentioning

confidence: 99%

“…While the mean annual air temperature depicted in Figure 3f does not exceed this threshold, under SSP585, 66.40% of the days, particularly during the growing season (April-September), recorded temperatures above 22°C. The multi-model ensemble mean/median consistently outperforms individual models under high temperature conditions (Asseng et al, 2019;Groh et al, 2022). Therefore, the development of intercomparison projects for crop modeling should be considered as an effective approach to mitigate uncertainties during periods of high temperature in future studies.…”

Section: Limitations Of Our Studymentioning

confidence: 99%

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Assessing Climate Change Impacts on Crop Yields and Exploring Adaptation Strategies in Northeast China

Xu,

Liang,

Wei

et al. 2024

Earth's Future

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Northeast China (NEC) is the most prominent grain‐producing region in China. However, it is currently facing significant impacts from climate change. Since the climate‐related impacts on crop yield in this region are a major concern for society in the future, quantifying climate change impacts on crop yields in NEC is essential to ensure future food security. This study aimed to quantify the effects of future climate change on crop yields in NEC and explore adaptation strategies using the Crop Growth Model (PCSE) driven by downscaled CMIP6 climate projections under four Shared Socioeconomic Pathways (SSPs) scenarios during 2015–2100. Results showed that there could be average reductions in crop yields of 21.4% for maize and 4.2% for soybean by the year 2100 under SSP585 compared to the 2015 baseline. The increasing temperature was the dominant factor in reducing yields, although elevated CO2 and precipitation offered partial compensation. The optimized planting date brought noticeable benefits for rice and soybean but had limited effects on maize due to heat stress. Relocating rice expansion eastward and implementing earlier planting increased yields by up to 50% but adversely decreased soybean and maize due to competition. This study enriches our comprehension of climate change impacts on NEC agriculture, while also quantifying potential benefits and constraints of evaluated adaptations. The proposed adaptations may help mitigate projected yield declines in other key agricultural regions across the globe. Adjusting crop management practices to capitalize on changing climate factors shows promise as a strategy for sustaining production globally.

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Section: Discussionmentioning

confidence: 99%

Section: Limitations Of Our Studymentioning

confidence: 99%

Assessing Climate Change Impacts on Crop Yields and Exploring Adaptation Strategies in Northeast China

Xu,

Liang,

Wei

et al. 2024

Earth's Future

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“…SWC is measured within each lysimeter at a depth of 0.1 m below the surface with time domain reflectometry probes (CS610, Campbell Scientific, North Logan, UT, USA) at a resolution of 0.1 % SWC, according to the manufacturer. More details on the technical specifications of lysimeter facilities within SOILCan are given in Pütz et al (2016), on excavation methods in Pütz and Groh (2023), and on the Selhausen facility in Groh et al (2022).…”

Section: Eddy Covariance and Lysimeter Measurementsmentioning

confidence: 99%

Interpretability of negative latent heat fluxes from eddy covariance measurements in dry conditions

Paulus,

Orth,

Lee

et al. 2024

Biogeosciences

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Abstract. It is known from arid and semi-arid ecosystems that atmospheric water vapor can directly be adsorbed by the soil matrix. Soil water vapor adsorption was typically neglected and only recently received attention because of improvements in measurement techniques. One technique rarely explored for the measurement of soil water vapor adsorption is eddy covariance (EC). Soil water vapor adsorption may be detectable as downwardly directed (i.e., negative) EC latent heat (λE) flux measurements under dry conditions, but a systematic assessment of the use of negative λE fluxes from EC flux stations to characterize adsorption is missing. We propose a classification method to characterize soil water vapor adsorption, excluding conditions of dew and fog when λE derived from EC is not trustworthy due to stable atmospheric conditions. We compare downwardly directed λE fluxes from EC with measurements from weighing lysimeters for 4 years in a Mediterranean savanna ecosystem and 3 years in a temperate agricultural site. Our aim is to assess if overnight water inputs from soil water vapor adsorption differ between ecosystems and how well they are detectable by EC. At the Mediterranean site, the lysimeters measured soil water vapor adsorption each summer, whereas at the temperate site, soil water vapor adsorption was much rarer and was measured predominantly under an extreme drought event in 2018. During 30 % of nights in the 4-year measurement period at the Mediterranean site, the EC technique detected downwardly directed λE fluxes of which 88.8 % were confirmed to be soil water vapor adsorption by at least one lysimeter. At the temperate site, downwardly directed λE fluxes were only recorded during 15 % of the nights, with only 36.8 % of half hours matching simultaneous lysimeter measurement of soil water vapor adsorption. This relationship slightly improved to 61 % under bare-soil conditions and extreme droughts. This underlines that soil water vapor adsorption is likely a much more relevant process in arid ecosystems compared to temperate ones and that the EC method was able to capture this difference. The comparisons of the amounts of soil water vapor adsorption between the two methods revealed a substantial underestimation of the EC compared to the lysimeters. This underestimation was, however, comparable with the underestimation in evaporation by the eddy covariance and improved in conditions of higher turbulence. Based on a random-forest-based feature selection, we found the mismatch between the methods being dominantly related to the site's inherent variability in soil conditions, namely soil water status, and soil (surface) temperature. We further demonstrate that although the water flux is very small with mean values of 0.04 or 0.06 mm per night for EC or lysimeter, respectively, it can be a substantial fraction of the diel soil water balance under dry conditions. Although the two instruments substantially differ with regard to the measured ratio of adsorption to evaporation over 24 h with 64 % and 25 % for the lysimeter and EC methods, they are in either case substantial. Given the usefulness of EC for detecting soil water vapor adsorption as demonstrated here, there is potential for investigating adsorption in more climate regions thanks to the greater abundance of EC measurements compared to lysimeter observations.

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“…Peters et al, 2017). Lysimeter data was used to determine the impact of changing climate and land use management on terrestrial hydrology and nutrient cycles for grasslands (Fu et al, 2017), and arable land (Groh et al, 2022). The temporally highly resolved measurements of hydraulic state variables and water fluxes have allowed to (a) advance the understanding of soil hydrology and inform new models (Hannes et al, 2016;Herbrich & Gerke, 2017) The TERENO design also extends the experimental catchment concept to stream reaches for improved understanding of aquatic ecosystem functions.…”

Section: Enabling Large-scale Experimentationmentioning

confidence: 99%

“…TERENO‐derived algorithms assure data quality and compute the water fluxes across the upper and lower boundaries of the lysimeters (e.g., Hannes et al., 2015; A. Peters et al., 2017). Lysimeter data was used to determine the impact of changing climate and land use management on terrestrial hydrology and nutrient cycles for grasslands (Fu et al., 2017), and arable land (Groh et al., 2022). The temporally highly resolved measurements of hydraulic state variables and water fluxes have allowed to (a) advance the understanding of soil hydrology and inform new models (Hannes et al., 2016; Herbrich & Gerke, 2017), (b) evaluate energy balance closure of eddy‐covariance stations (Mauder et al., 2018), (c) test crop yield models (Kamali et al., 2022), (d) predict impacts of climate change water use efficiency and plant growths (Jarvis et al., 2022), and (e) validate large scale model simulations of the German Drought Monitor (Boeing et al., 2022) and remotely sensed products (Trigo et al., 2018).…”

Section: Tereno—a Network Of Four Integrated Environmental Observatoriesmentioning

confidence: 99%

Fifteen Years of Integrated Terrestrial Environmental Observatories (TERENO) in Germany: Functions, Services, and Lessons Learned

Zacharias,

Loescher,

Bogena

et al. 2024

Earth's Future

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The need to develop and provide integrated observation systems to better understand and manage global and regional environmental change is one of the major challenges facing Earth system science today. In 2008, the German Helmholtz Association took up this challenge and launched the German research infrastructure TERrestrial ENvironmental Observatories (TERENO). The aim of TERENO is the establishment and maintenance of a network of observatories as a basis for an interdisciplinary and long‐term research program to investigate the effects of global environmental change on terrestrial ecosystems and their socio‐economic consequences. State‐of‐the‐art methods from the field of environmental monitoring, geophysics, remote sensing, and modeling are used to record and analyze states and fluxes in different environmental disciplines from groundwater through the vadose zone, surface water, and biosphere, up to the lower atmosphere. Over the past 15 years we have collectively gained experience in operating a long‐term observing network, thereby overcoming unexpected operational and institutional challenges, exceeding expectations, and facilitating new research. Today, the TERENO network is a key pillar for environmental modeling and forecasting in Germany, an information hub for practitioners and policy stakeholders in agriculture, forestry, and water management at regional to national levels, a nucleus for international collaboration, academic training and scientific outreach, an important anchor for large‐scale experiments, and a trigger for methodological innovation and technological progress. This article describes TERENO's key services and functions, presents the main lessons learned from this 15‐year effort, and emphasizes the need to continue long‐term integrated environmental monitoring programmes in the future.

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Same soil, different climate: Crop model intercomparison on translocated lysimeters

Cited by 8 publications

References 118 publications

Assessing Climate Change Impacts on Crop Yields and Exploring Adaptation Strategies in Northeast China

Assessing Climate Change Impacts on Crop Yields and Exploring Adaptation Strategies in Northeast China

Interpretability of negative latent heat fluxes from eddy covariance measurements in dry conditions

Fifteen Years of Integrated Terrestrial Environmental Observatories (TERENO) in Germany: Functions, Services, and Lessons Learned

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