Soil and tree stem xylem water isotope data from two pan-European sampling campaigns

Marco M. Lehmann; Josie Geris; Ilja Van Meerveld; Daniele Penna; Youri Rothfuss; Matteo Verdone; Pertti Ala-Aho; Matyas Arvai; Alise Babre; Philippe Balandier; Fabian Bernhard; Lukrecija Butorac; Simon D. Carrière; Natalie C. Ceperley; Zuosinan Chen; Alicia Correa; Haoyu Diao; David Dubbert; Maren Dubbert; Fabio Ercoli; Marius G. Floriancic; Alligin Ghazoul; Teresa E. Gimeno; Damien Gounelle; Frank Hagedorn; Christophe Hissler; Frédéric Huneau; Alberto Iraheta; Tamara Jakovljević; Nerantzis Kazakis; Zoltan Kern; Laura Kinzinger; Karl Knaebel; Johannes Kobler; Jiri Kocum; Charlotte Koeber; Gerbrand Koren; Angelika Kübert; Dawid Kupka; Samuel Le Gall; Aleksi Lehtonen; Thomas Leydier; Philippe Malagoli; Francesca Sofia Manca Di Villahermosa; Chiara Marchina; Núria Martínez-Carreras; Nicolas Martin-Stpaul; Hannu Marttila; Aline Meyer Oliveira; Gael Monvoisin; Natalie Orlowski; Kadi Palmik-Das; Aurel Persoiu; Andrei Popa; Egor Prikaziuk; Cécile Quantin; Katja T. Rinne-Garmston; Clara Rohde; Martin Sanda; Matthias Saurer; Daniel Schulz; Michael P. Stockinger; Christine Stumpp; Jean Stéphane Vénisse; Lukas Vlcek; Stylianos Voudouris; Björn Weeser; Mark E. Wilkinson; Giulia Zuecco; Katrin Meusburger

doi:10.5194/essd-17-6129-2025

Soil and tree stem xylem water isotope data from two pan-European sampling campaigns

Marco M. Lehmann^*
, Josie Geris
, Ilja Van Meerveld
, Daniele Penna
, Youri Rothfuss
, Matteo Verdone
, Pertti Ala-Aho
, Matyas Arvai
, Alise Babre
, Philippe Balandier
, Fabian Bernhard
, Lukrecija Butorac
, Simon D. Carrière
, Natalie C. Ceperley
, Zuosinan Chen
, Alicia Correa
, Haoyu Diao
, David Dubbert
, Maren Dubbert
, Fabio Ercoli

Marius G. Floriancic, Alligin Ghazoul, Teresa E. Gimeno, Damien Gounelle, Frank Hagedorn, Christophe Hissler, Frédéric Huneau, Alberto Iraheta, Tamara Jakovljević, Nerantzis Kazakis, Zoltan Kern, Laura Kinzinger, Karl Knaebel, Johannes Kobler, Jiri Kocum, Charlotte Koeber, Gerbrand Koren, Angelika Kübert, Dawid Kupka, Samuel Le Gall, Aleksi Lehtonen, Thomas Leydier, Philippe Malagoli, Francesca Sofia Manca Di Villahermosa, Chiara Marchina, Núria Martínez-Carreras, Nicolas Martin-Stpaul, Hannu Marttila, Aline Meyer Oliveira, Gael Monvoisin, Natalie Orlowski, Kadi Palmik-Das, Aurel Persoiu, Andrei Popa, Egor Prikaziuk, Cécile Quantin, Katja T. Rinne-Garmston, Clara Rohde, Martin Sanda, Matthias Saurer, Daniel Schulz, Michael P. Stockinger, Christine Stumpp, Jean Stéphane Vénisse, Lukas Vlcek, Stylianos Voudouris, Björn Weeser, Mark E. Wilkinson, Giulia Zuecco, Katrin Meusburger

^*Corresponding author for this work

Department of Geology

Swiss Federal Institute for Forest, Snow and Landscape Research
University of Aberdeen
University of Zurich
University of Florence
Jülich Research Centre
University of Oulu
Centre for Agricultural Research
Université Clermont Auvergne
Institute for Adriatic Crops and Karst Reclamation
CNRS
University of Bern
Justus Liebig University Giessen
Leibniz Centre for Agricultural Landscape Research
Estonian University of Life Sciences
Swiss Federal Institute of Technology Zurich
Cerdanyola del Vallès
INRAE
Luxembourg Institute of Science and Technology
Università di Corsica Pasquale Paoli
Technical University of Braunschweig
European Forest Institute
University of Patras
Institute for Geological and Geochemical Research
University of Freiburg
Environment Agency Austria
Charles University
Utrecht University
University of Helsinki
University of Agriculture in Krakow
Luke Natural Resources Institute Finland
University of Padua
Université Paris-Saclay
Technische Universität Dresden
Romanian Academy
Forest Research and Management Institute
University of Twente
Czech Technical University in Prague
University of Natural Resources and Life Sciences, Vienna
Czech Academy of Sciences
IFP Énergies nouvelles
The James Hutton Institute

Research output: Contribution to journal › Article › peer-review

1 Citation (Scopus)

Abstract

The stable isotope ratios of hydrogen (δ2H) and oxygen (δ18O) are useful for studying ecohydrological dynamics in forests. However, most isotope-based eco-hydrological studies are limited to single sites, resulting in a lack of large-scale isotope data for understanding tree water uptake. Here, we provide a first systematic isotope dataset for soil and stem xylem water collected during two pan-European sampling campaigns at 40 beech (Fagus sylvatica), spruce (Picea abies), or mixed beech-spruce forest sites in spring and summer 2023 (10.16904/envidat.542, Lehmann et al., 2024). The dataset is complemented by additional site-, soil-, and tree-specific metadata. The samples and metadata were collected by different researchers across Europe following a standardized protocol. Soil samples were taken at up to 5 depths (ranging from 0 to 90 cm) and stem xylem samples from the trunks of three beech and/or spruce trees per site. All samples were sent to a single laboratory, where all analytical work was conducted. Water was extracted using cryogenic vacuum distillation and analyzed with an isotope laser spectrometer. Additionally, a subset of the samples was analyzed with an isotope ratio mass spectrometer. Data quality checks revealed a high mean total extraction efficiency, mean water amount (>1mL), accuracy, and precision. The isotopic signature of soil and stem xylem water varied as a function of the geographic origin and changed from spring to summer across all sites. While δ2H and δ18O were strongly correlated, the soil water data plotted closer to the Global Meteoric Water Line (GMWL) than the stem xylem water. Specifically, the δ2H values of the xylem water were more enriched than those of the soil water, leading to a systematic deviation from the GMWL. Isotopic enrichment of the stem xylem water at mixed forest sites was larger for spruce trees than for beech trees. This dataset is particularly useful for large-scale studies on plant water use, ecohydrological model testing, and isotope mapping across Europe.

Original language	English
Pages (from-to)	6129-6147
Number of pages	19
Journal	Earth System Science Data
Volume	17
Issue number	11
DOIs	https://doi.org/10.5194/essd-17-6129-2025
Publication status	Published - 14 Nov 2025

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10.5194/essd-17-6129-2025

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Lehmann, M. M., Geris, J., Van Meerveld, I., Penna, D., Rothfuss, Y., Verdone, M., Ala-Aho, P., Arvai, M., Babre, A., Balandier, P., Bernhard, F., Butorac, L., Carrière, S. D., Ceperley, N. C., Chen, Z., Correa, A., Diao, H., Dubbert, D., Dubbert, M., ... Meusburger, K. (2025). Soil and tree stem xylem water isotope data from two pan-European sampling campaigns. Earth System Science Data, 17(11), 6129-6147. https://doi.org/10.5194/essd-17-6129-2025

@article{eb04591a49764595bfb8ab7b84f2ecbf,

title = "Soil and tree stem xylem water isotope data from two pan-European sampling campaigns",

abstract = "The stable isotope ratios of hydrogen (δ2H) and oxygen (δ18O) are useful for studying ecohydrological dynamics in forests. However, most isotope-based eco-hydrological studies are limited to single sites, resulting in a lack of large-scale isotope data for understanding tree water uptake. Here, we provide a first systematic isotope dataset for soil and stem xylem water collected during two pan-European sampling campaigns at 40 beech (Fagus sylvatica), spruce (Picea abies), or mixed beech-spruce forest sites in spring and summer 2023 (10.16904/envidat.542, Lehmann et al., 2024). The dataset is complemented by additional site-, soil-, and tree-specific metadata. The samples and metadata were collected by different researchers across Europe following a standardized protocol. Soil samples were taken at up to 5 depths (ranging from 0 to 90 cm) and stem xylem samples from the trunks of three beech and/or spruce trees per site. All samples were sent to a single laboratory, where all analytical work was conducted. Water was extracted using cryogenic vacuum distillation and analyzed with an isotope laser spectrometer. Additionally, a subset of the samples was analyzed with an isotope ratio mass spectrometer. Data quality checks revealed a high mean total extraction efficiency, mean water amount (>1mL), accuracy, and precision. The isotopic signature of soil and stem xylem water varied as a function of the geographic origin and changed from spring to summer across all sites. While δ2H and δ18O were strongly correlated, the soil water data plotted closer to the Global Meteoric Water Line (GMWL) than the stem xylem water. Specifically, the δ2H values of the xylem water were more enriched than those of the soil water, leading to a systematic deviation from the GMWL. Isotopic enrichment of the stem xylem water at mixed forest sites was larger for spruce trees than for beech trees. This dataset is particularly useful for large-scale studies on plant water use, ecohydrological model testing, and isotope mapping across Europe.",

author = "Lehmann, \{Marco M.\} and Josie Geris and \{Van Meerveld\}, Ilja and Daniele Penna and Youri Rothfuss and Matteo Verdone and Pertti Ala-Aho and Matyas Arvai and Alise Babre and Philippe Balandier and Fabian Bernhard and Lukrecija Butorac and Carri{\`e}re, \{Simon D.\} and Ceperley, \{Natalie C.\} and Zuosinan Chen and Alicia Correa and Haoyu Diao and David Dubbert and Maren Dubbert and Fabio Ercoli and Floriancic, \{Marius G.\} and Alligin Ghazoul and Gimeno, \{Teresa E.\} and Damien Gounelle and Frank Hagedorn and Christophe Hissler and Fr{\'e}d{\'e}ric Huneau and Alberto Iraheta and Tamara Jakovljevi{\'c} and Nerantzis Kazakis and Zoltan Kern and Laura Kinzinger and Karl Knaebel and Johannes Kobler and Jiri Kocum and Charlotte Koeber and Gerbrand Koren and Angelika K{\"u}bert and Dawid Kupka and \{Le Gall\}, Samuel and Aleksi Lehtonen and Thomas Leydier and Philippe Malagoli and \{Manca Di Villahermosa\}, \{Francesca Sofia\} and Chiara Marchina and N{\'u}ria Mart{\'i}nez-Carreras and Nicolas Martin-Stpaul and Hannu Marttila and \{Meyer Oliveira\}, Aline and Gael Monvoisin and Natalie Orlowski and Kadi Palmik-Das and Aurel Persoiu and Andrei Popa and Egor Prikaziuk and C{\'e}cile Quantin and Rinne-Garmston, \{Katja T.\} and Clara Rohde and Martin Sanda and Matthias Saurer and Daniel Schulz and Stockinger, \{Michael P.\} and Christine Stumpp and V{\'e}nisse, \{Jean St{\'e}phane\} and Lukas Vlcek and Stylianos Voudouris and Bj{\"o}rn Weeser and Wilkinson, \{Mark E.\} and Giulia Zuecco and Katrin Meusburger",

note = "Publisher Copyright: {\textcopyright} 2025 Marco M. Lehmann et al.",

year = "2025",

month = nov,

day = "14",

doi = "10.5194/essd-17-6129-2025",

language = "English",

volume = "17",

pages = "6129--6147",

journal = "Earth System Science Data",

issn = "1866-3508",

publisher = "Copernicus Publications",

number = "11",

}

Lehmann, MM, Geris, J, Van Meerveld, I, Penna, D, Rothfuss, Y, Verdone, M, Ala-Aho, P, Arvai, M, Babre, A, Balandier, P, Bernhard, F, Butorac, L, Carrière, SD, Ceperley, NC, Chen, Z, Correa, A, Diao, H, Dubbert, D, Dubbert, M, Ercoli, F, Floriancic, MG, Ghazoul, A, Gimeno, TE, Gounelle, D, Hagedorn, F, Hissler, C, Huneau, F, Iraheta, A, Jakovljević, T, Kazakis, N, Kern, Z, Kinzinger, L, Knaebel, K, Kobler, J, Kocum, J, Koeber, C, Koren, G, Kübert, A, Kupka, D, Le Gall, S, Lehtonen, A, Leydier, T, Malagoli, P, Manca Di Villahermosa, FS, Marchina, C, Martínez-Carreras, N, Martin-Stpaul, N, Marttila, H, Meyer Oliveira, A, Monvoisin, G, Orlowski, N, Palmik-Das, K, Persoiu, A, Popa, A, Prikaziuk, E, Quantin, C, Rinne-Garmston, KT, Rohde, C, Sanda, M, Saurer, M, Schulz, D, Stockinger, MP, Stumpp, C, Vénisse, JS, Vlcek, L, Voudouris, S, Weeser, B, Wilkinson, ME, Zuecco, G & Meusburger, K 2025, 'Soil and tree stem xylem water isotope data from two pan-European sampling campaigns', Earth System Science Data, vol. 17, no. 11, pp. 6129-6147. https://doi.org/10.5194/essd-17-6129-2025

TY - JOUR

T1 - Soil and tree stem xylem water isotope data from two pan-European sampling campaigns

AU - Lehmann, Marco M.

AU - Geris, Josie

AU - Van Meerveld, Ilja

AU - Penna, Daniele

AU - Rothfuss, Youri

AU - Verdone, Matteo

AU - Ala-Aho, Pertti

AU - Arvai, Matyas

AU - Babre, Alise

AU - Balandier, Philippe

AU - Bernhard, Fabian

AU - Butorac, Lukrecija

AU - Carrière, Simon D.

AU - Ceperley, Natalie C.

AU - Chen, Zuosinan

AU - Correa, Alicia

AU - Diao, Haoyu

AU - Dubbert, David

AU - Dubbert, Maren

AU - Ercoli, Fabio

AU - Floriancic, Marius G.

AU - Ghazoul, Alligin

AU - Gimeno, Teresa E.

AU - Gounelle, Damien

AU - Hagedorn, Frank

AU - Hissler, Christophe

AU - Huneau, Frédéric

AU - Iraheta, Alberto

AU - Jakovljević, Tamara

AU - Kazakis, Nerantzis

AU - Kern, Zoltan

AU - Kinzinger, Laura

AU - Knaebel, Karl

AU - Kobler, Johannes

AU - Kocum, Jiri

AU - Koeber, Charlotte

AU - Koren, Gerbrand

AU - Kübert, Angelika

AU - Kupka, Dawid

AU - Le Gall, Samuel

AU - Lehtonen, Aleksi

AU - Leydier, Thomas

AU - Malagoli, Philippe

AU - Manca Di Villahermosa, Francesca Sofia

AU - Marchina, Chiara

AU - Martínez-Carreras, Núria

AU - Martin-Stpaul, Nicolas

AU - Marttila, Hannu

AU - Meyer Oliveira, Aline

AU - Monvoisin, Gael

AU - Orlowski, Natalie

AU - Palmik-Das, Kadi

AU - Persoiu, Aurel

AU - Popa, Andrei

AU - Prikaziuk, Egor

AU - Quantin, Cécile

AU - Rinne-Garmston, Katja T.

AU - Rohde, Clara

AU - Sanda, Martin

AU - Saurer, Matthias

AU - Schulz, Daniel

AU - Stockinger, Michael P.

AU - Stumpp, Christine

AU - Vénisse, Jean Stéphane

AU - Vlcek, Lukas

AU - Voudouris, Stylianos

AU - Weeser, Björn

AU - Wilkinson, Mark E.

AU - Zuecco, Giulia

AU - Meusburger, Katrin

PY - 2025/11/14

Y1 - 2025/11/14

N2 - The stable isotope ratios of hydrogen (δ2H) and oxygen (δ18O) are useful for studying ecohydrological dynamics in forests. However, most isotope-based eco-hydrological studies are limited to single sites, resulting in a lack of large-scale isotope data for understanding tree water uptake. Here, we provide a first systematic isotope dataset for soil and stem xylem water collected during two pan-European sampling campaigns at 40 beech (Fagus sylvatica), spruce (Picea abies), or mixed beech-spruce forest sites in spring and summer 2023 (10.16904/envidat.542, Lehmann et al., 2024). The dataset is complemented by additional site-, soil-, and tree-specific metadata. The samples and metadata were collected by different researchers across Europe following a standardized protocol. Soil samples were taken at up to 5 depths (ranging from 0 to 90 cm) and stem xylem samples from the trunks of three beech and/or spruce trees per site. All samples were sent to a single laboratory, where all analytical work was conducted. Water was extracted using cryogenic vacuum distillation and analyzed with an isotope laser spectrometer. Additionally, a subset of the samples was analyzed with an isotope ratio mass spectrometer. Data quality checks revealed a high mean total extraction efficiency, mean water amount (>1mL), accuracy, and precision. The isotopic signature of soil and stem xylem water varied as a function of the geographic origin and changed from spring to summer across all sites. While δ2H and δ18O were strongly correlated, the soil water data plotted closer to the Global Meteoric Water Line (GMWL) than the stem xylem water. Specifically, the δ2H values of the xylem water were more enriched than those of the soil water, leading to a systematic deviation from the GMWL. Isotopic enrichment of the stem xylem water at mixed forest sites was larger for spruce trees than for beech trees. This dataset is particularly useful for large-scale studies on plant water use, ecohydrological model testing, and isotope mapping across Europe.

AB - The stable isotope ratios of hydrogen (δ2H) and oxygen (δ18O) are useful for studying ecohydrological dynamics in forests. However, most isotope-based eco-hydrological studies are limited to single sites, resulting in a lack of large-scale isotope data for understanding tree water uptake. Here, we provide a first systematic isotope dataset for soil and stem xylem water collected during two pan-European sampling campaigns at 40 beech (Fagus sylvatica), spruce (Picea abies), or mixed beech-spruce forest sites in spring and summer 2023 (10.16904/envidat.542, Lehmann et al., 2024). The dataset is complemented by additional site-, soil-, and tree-specific metadata. The samples and metadata were collected by different researchers across Europe following a standardized protocol. Soil samples were taken at up to 5 depths (ranging from 0 to 90 cm) and stem xylem samples from the trunks of three beech and/or spruce trees per site. All samples were sent to a single laboratory, where all analytical work was conducted. Water was extracted using cryogenic vacuum distillation and analyzed with an isotope laser spectrometer. Additionally, a subset of the samples was analyzed with an isotope ratio mass spectrometer. Data quality checks revealed a high mean total extraction efficiency, mean water amount (>1mL), accuracy, and precision. The isotopic signature of soil and stem xylem water varied as a function of the geographic origin and changed from spring to summer across all sites. While δ2H and δ18O were strongly correlated, the soil water data plotted closer to the Global Meteoric Water Line (GMWL) than the stem xylem water. Specifically, the δ2H values of the xylem water were more enriched than those of the soil water, leading to a systematic deviation from the GMWL. Isotopic enrichment of the stem xylem water at mixed forest sites was larger for spruce trees than for beech trees. This dataset is particularly useful for large-scale studies on plant water use, ecohydrological model testing, and isotope mapping across Europe.

UR - https://www.scopus.com/pages/publications/105021844018

U2 - 10.5194/essd-17-6129-2025

DO - 10.5194/essd-17-6129-2025

M3 - Article

AN - SCOPUS:105021844018

SN - 1866-3508

VL - 17

SP - 6129

EP - 6147

JO - Earth System Science Data

JF - Earth System Science Data

IS - 11

ER -

Soil and tree stem xylem water isotope data from two pan-European sampling campaigns

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