The impact of water-soluble environmental aerosols on the drought tolerance of forest treesa Germany-wide field study
The impact of water-soluble environmental aerosols on the drought tolerance of forest trees
a Germany-wide field study
This document has got an embargo.
Date of Embargo
01.07.2026Type of Scholarly Publication
DissertationDate of Exam
29.01.2026Date of Publication
02.03.2026Advisor
Burkhardt, JürgenCo-Referee
Becker, MathiasMetadata
Show full item record
Citable Links 
Abstract
Forest trees in Germany and around the world are showing increasing drought damage symptoms and higher mortality rates due to climate change. Trees suffer direct damage from drought periods and heat waves, and forest ecosystems are becoming less resilient, which increases the damage caused by biotic and abiotic factors. Hygroscopic aerosols could be another largely overlooked factor increasing drought stress in plants. Since the Industrial Revolution, aerosol pollution has increased significantly. Some of these aerosols are hygroscopic salts, that can draw moisture from the air and liquefy as a result (deliquescence). The HAS hypothesis (HAS: hydraulically activated stomata; Burkhardt, 2010) is a mechanistic model explaining the connection between hygroscopic salts and drought stress. According to the hypothesis, hygroscopic salts can activate stomata by forming a connection between the substomatal cavity and the leaf surface. Through this connection, liquid water can be transported in a bidirectional flow. This can lead to increased, uncontrollable water loss via the stomata.
The present study investigated the influence of deposited hygroscopic aerosol particles on the drought tolerance of forest trees. In this German-wide field study, leaves and needles of Fagus sylvatica (European beech), Quercus petraea (sessile oak), Pinus sylvestris (Scots pine), and Picea abies (Norway spruce) were sampled over a period of three years. Minimum epidermal conductance (gmin) and the water potential at turgor loss point (πTLP) were measured as indicators of drought tolerance. To determine hygroscopic aerosol deposition, the leaves and needles were washed, and the chemical composition of the wash solution was analyzed. The nutritional status of the leaves and needles and their nitrogen and carbon isotopic ratios were analyzed. The hydrophobicity of the surfaces was determined using contact angles. A greenhouse experiment compared needle and leaf surfaces with and without aerosols using electron microscopy and wax analysis.
The main novelty of this study is that significant correlations were found between the concentration of the washable ions and the drought tolerance parameters for each tree species, despite highly variable conditions. The existence of these significant correlations makes causal relationships likely, as they were established based on a mechanistic hypothesis and a targeted experimental approach.
In P. sylvestris, gmin and sodium were positively and significantly correlated. This supports the study's main hypothesis that aerosol deposition hydraulically activates stomata, thereby increasing gmin and reducing drought tolerance. This result corresponds with the filter approach to canopy interaction by Ulrich (1983), in which sodium does not interact with the leaf surfaces, allowing dry deposition to be inferred. For P. sylvestris, Ulrich's approach can also be used to explain the buffering of H3O+ by the base cations.
For the other tree species, a large number significant correlations between washable ions and gmin as well as πTLP were also recorded. These results are largely consistent with the HAS hypothesis, but in some cases new perspectives or assumptions regarding canopy interaction are necessary. Over the course of the year, the correlations demonstrate that HAS develops faster in Q. petraea than in P. sylvestris. Increased HAS and thus higher gmin then leads to more effective ion uptake, which also explains the significant negative correlations between the gmin and the ions. A rapid build-up of HAS can be advantageous for trees, as it enables them to absorb both nutrients and water through their stomata. The potentially functionally adapted leaf surfaces of tree species, combined with increasing atmospheric drought due to climate change and insufficiently strong reductions in air pollution, pose a drought risk for forests. The entire field of aerosol-plant interactions, should be investigated further, as it is important for both the nutrient and the water balance of trees. Der Einfluss wasserlöslicher Aerosole auf die Trockentoleranz von Waldbäumen : eine deutschlandweite Feldstudie
Waldbäume in Deutschland und weltweit zeigen zunehmende Schäden und erhöhte Mortalitätsraten durch die Folgen des Klimawandels. Durch Dürreperioden und Hitzewellen gibt es direkte Trockenschäden an Bäumen sowie eine Abnahme der Resilienz der Waldökosysteme, was auch Schäden durch biotische und abiotische Faktoren verstärkt. Ein bisher weitestgehend unbeachteter Faktor, der möglicherweise den Trockenstress in Pflanzen erhöht, sind hygroskopische Aerosole. Die Aerosolbelastung weltweit hat seit der Industrialisierung stark zugenommen. Hygroskopische Salze als Teil der Aerosole können die Feuchtigkeit aus der Luft ziehen und sich dadurch verflüssigen (Deliqueszenz). Ein mechanistisches Erklärungsmodell für die Zusammenhänge zwischen Aerosoleinträgen und Trockenstress bietet die HAS-Hypothese (HAS: hydraulisch aktivierte Stomata) nach Burkhardt (2010): hygroskopische Salze bilden durch Deliqueszenz sehr dünne Wasserfilme zwischen der substomatären Höhle und der Blattoberfläche, entlang derer flüssiges Wasser bidirektional transportiert werden kann. Eine Folge ist ein erhöhter stomatärer Wasserverlust, der für die Pflanze nicht über die Spaltöffnungsweite kontrollierbar ist.
In der vorliegenden Untersuchung wurde der Einfluss abgelagerter atmosphärischer Aerosolpartikel auf die Trockentoleranz von Waldbäumen im Freiland untersucht. Hierzu wurden deutschlandweit über drei Jahre hinweg Blätter und Nadeln von Fagus sylvatica (Rotbuche), Quercus petraea (Traubeneiche), Pinus sylvestris (Waldkiefer) und Picea abies (gemeine Fichte) beprobt. Als Indikatoren für Trockentoleranz wurden die minimale epidermale Leitfähigkeit (gmin) sowie das Wasserpotential am Turgorverlustpunkt (πTLP) gemessen. Zur Bestimmung hygroskopischer Aerosolablagerungen wurden Blätter und Nadeln abgewaschen und die chemische Zusammensetzung und Konzentration der Waschlösungen analysiert. Der Ernährungszustand der Blätter und Nadeln sowie ihre Stickstoff- und Kohlenstoff-Isotopenverhältnisse wurden analysiert. Die Hydrophobizität der Oberflächen wurde über Kontaktwinkel bestimmt. Ein Gewächshausversuch verglich Nadeloberflächen mit und ohne Aerosole elektronenmikroskopisch und durch Wachsanalysen.
Der wesentliche Neuigkeitswert der vorliegenden Studie liegt darin begründet, dass es pro Baumart über alle Proben hinweg trotz stark variabler Bedingungen in sehr hohem Ausmaß möglich war, signifikante Korrelationen zwischen der Konzentration abwaschbarer Ionen und den Trockentoleranzparametern zu detektieren. Die Existenz dieser signifikanten Korrelationen machen kausale Zusammenhänge wahrscheinlich, da diese auf der Basis einer mechanistischen Hypothese und eines zielgerichteten experimentellen Ansatzes zustande kamen.
Bei P. sylvestris waren gmin und Natrium signifikant positiv miteinander korreliert. Dies unterstützt die Haupthypothese der Studie, dass durch die Aerosoldeposition Stomata hydraulisch aktiviert werden und sich damit gmin erhöht, was eine Verringerung der Trockentoleranz bedeutet. Dieses Ergebnis korrespondiert mit dem Filteransatz der Kronenraumbilanz nach Ulrich (1983), wonach Natrium nicht mit den Oberflächen interagiert und somit die trockene Deposition daraus ablesbar ist. Für P. sylvestris kann auch das Abpuffern von H3O+ und die Abpufferung der Säure-Ionen durch die basischen Kationen nachvollzogen werden, die sich ebenfalls aus dem Ulrich'schen Ansatz ergeben.
Für die anderen Baumarten wurde ebenfalls eine Vielzahl von weiteren signifikanten Korrelationen zwischen den abwaschbaren Ionen mit gmin sowie mit πTLP registriert. Auch diese Ergebnisse lassen sich weitgehend mit der HAS-Hypothese in Einklang bringen. So zeigt sich im Jahresverlauf bei Q. petraea durch die Korrelationen ein schnellerer und weiter gehender Aufbau von HAS als bei P. sylvestris. Verstärktes HAS und damit höheres gmin führt dann zur effektiveren Aufnahme von Ionen, wodurch sich auch signifikant negative Korrelationen zwischen gmin und Ionen erklären lassen. Der gesamte, bislang stark vernachlässigte Bereich der Aerosol-Pflanze-Interaktion sollte weiter untersucht werden, da er sowohl für den Nährstoff- als auch den Wasserhaushalt von Bäumen bedeutsam ist.
The present study investigated the influence of deposited hygroscopic aerosol particles on the drought tolerance of forest trees. In this German-wide field study, leaves and needles of Fagus sylvatica (European beech), Quercus petraea (sessile oak), Pinus sylvestris (Scots pine), and Picea abies (Norway spruce) were sampled over a period of three years. Minimum epidermal conductance (gmin) and the water potential at turgor loss point (πTLP) were measured as indicators of drought tolerance. To determine hygroscopic aerosol deposition, the leaves and needles were washed, and the chemical composition of the wash solution was analyzed. The nutritional status of the leaves and needles and their nitrogen and carbon isotopic ratios were analyzed. The hydrophobicity of the surfaces was determined using contact angles. A greenhouse experiment compared needle and leaf surfaces with and without aerosols using electron microscopy and wax analysis.
The main novelty of this study is that significant correlations were found between the concentration of the washable ions and the drought tolerance parameters for each tree species, despite highly variable conditions. The existence of these significant correlations makes causal relationships likely, as they were established based on a mechanistic hypothesis and a targeted experimental approach.
In P. sylvestris, gmin and sodium were positively and significantly correlated. This supports the study's main hypothesis that aerosol deposition hydraulically activates stomata, thereby increasing gmin and reducing drought tolerance. This result corresponds with the filter approach to canopy interaction by Ulrich (1983), in which sodium does not interact with the leaf surfaces, allowing dry deposition to be inferred. For P. sylvestris, Ulrich's approach can also be used to explain the buffering of H3O+ by the base cations.
For the other tree species, a large number significant correlations between washable ions and gmin as well as πTLP were also recorded. These results are largely consistent with the HAS hypothesis, but in some cases new perspectives or assumptions regarding canopy interaction are necessary. Over the course of the year, the correlations demonstrate that HAS develops faster in Q. petraea than in P. sylvestris. Increased HAS and thus higher gmin then leads to more effective ion uptake, which also explains the significant negative correlations between the gmin and the ions. A rapid build-up of HAS can be advantageous for trees, as it enables them to absorb both nutrients and water through their stomata. The potentially functionally adapted leaf surfaces of tree species, combined with increasing atmospheric drought due to climate change and insufficiently strong reductions in air pollution, pose a drought risk for forests. The entire field of aerosol-plant interactions, should be investigated further, as it is important for both the nutrient and the water balance of trees.
Waldbäume in Deutschland und weltweit zeigen zunehmende Schäden und erhöhte Mortalitätsraten durch die Folgen des Klimawandels. Durch Dürreperioden und Hitzewellen gibt es direkte Trockenschäden an Bäumen sowie eine Abnahme der Resilienz der Waldökosysteme, was auch Schäden durch biotische und abiotische Faktoren verstärkt. Ein bisher weitestgehend unbeachteter Faktor, der möglicherweise den Trockenstress in Pflanzen erhöht, sind hygroskopische Aerosole. Die Aerosolbelastung weltweit hat seit der Industrialisierung stark zugenommen. Hygroskopische Salze als Teil der Aerosole können die Feuchtigkeit aus der Luft ziehen und sich dadurch verflüssigen (Deliqueszenz). Ein mechanistisches Erklärungsmodell für die Zusammenhänge zwischen Aerosoleinträgen und Trockenstress bietet die HAS-Hypothese (HAS: hydraulisch aktivierte Stomata) nach Burkhardt (2010): hygroskopische Salze bilden durch Deliqueszenz sehr dünne Wasserfilme zwischen der substomatären Höhle und der Blattoberfläche, entlang derer flüssiges Wasser bidirektional transportiert werden kann. Eine Folge ist ein erhöhter stomatärer Wasserverlust, der für die Pflanze nicht über die Spaltöffnungsweite kontrollierbar ist.
In der vorliegenden Untersuchung wurde der Einfluss abgelagerter atmosphärischer Aerosolpartikel auf die Trockentoleranz von Waldbäumen im Freiland untersucht. Hierzu wurden deutschlandweit über drei Jahre hinweg Blätter und Nadeln von Fagus sylvatica (Rotbuche), Quercus petraea (Traubeneiche), Pinus sylvestris (Waldkiefer) und Picea abies (gemeine Fichte) beprobt. Als Indikatoren für Trockentoleranz wurden die minimale epidermale Leitfähigkeit (gmin) sowie das Wasserpotential am Turgorverlustpunkt (πTLP) gemessen. Zur Bestimmung hygroskopischer Aerosolablagerungen wurden Blätter und Nadeln abgewaschen und die chemische Zusammensetzung und Konzentration der Waschlösungen analysiert. Der Ernährungszustand der Blätter und Nadeln sowie ihre Stickstoff- und Kohlenstoff-Isotopenverhältnisse wurden analysiert. Die Hydrophobizität der Oberflächen wurde über Kontaktwinkel bestimmt. Ein Gewächshausversuch verglich Nadeloberflächen mit und ohne Aerosole elektronenmikroskopisch und durch Wachsanalysen.
Der wesentliche Neuigkeitswert der vorliegenden Studie liegt darin begründet, dass es pro Baumart über alle Proben hinweg trotz stark variabler Bedingungen in sehr hohem Ausmaß möglich war, signifikante Korrelationen zwischen der Konzentration abwaschbarer Ionen und den Trockentoleranzparametern zu detektieren. Die Existenz dieser signifikanten Korrelationen machen kausale Zusammenhänge wahrscheinlich, da diese auf der Basis einer mechanistischen Hypothese und eines zielgerichteten experimentellen Ansatzes zustande kamen.
Bei P. sylvestris waren gmin und Natrium signifikant positiv miteinander korreliert. Dies unterstützt die Haupthypothese der Studie, dass durch die Aerosoldeposition Stomata hydraulisch aktiviert werden und sich damit gmin erhöht, was eine Verringerung der Trockentoleranz bedeutet. Dieses Ergebnis korrespondiert mit dem Filteransatz der Kronenraumbilanz nach Ulrich (1983), wonach Natrium nicht mit den Oberflächen interagiert und somit die trockene Deposition daraus ablesbar ist. Für P. sylvestris kann auch das Abpuffern von H3O+ und die Abpufferung der Säure-Ionen durch die basischen Kationen nachvollzogen werden, die sich ebenfalls aus dem Ulrich'schen Ansatz ergeben.
Für die anderen Baumarten wurde ebenfalls eine Vielzahl von weiteren signifikanten Korrelationen zwischen den abwaschbaren Ionen mit gmin sowie mit πTLP registriert. Auch diese Ergebnisse lassen sich weitgehend mit der HAS-Hypothese in Einklang bringen. So zeigt sich im Jahresverlauf bei Q. petraea durch die Korrelationen ein schnellerer und weiter gehender Aufbau von HAS als bei P. sylvestris. Verstärktes HAS und damit höheres gmin führt dann zur effektiveren Aufnahme von Ionen, wodurch sich auch signifikant negative Korrelationen zwischen gmin und Ionen erklären lassen. Der gesamte, bislang stark vernachlässigte Bereich der Aerosol-Pflanze-Interaktion sollte weiter untersucht werden, da er sowohl für den Nährstoff- als auch den Wasserhaushalt von Bäumen bedeutsam ist.
Subjects
Aerosole, Hydraulische Aktivierung von Stomata, Trockentoleranz, Waldbäume, aerosols, hydraulic activation of stomata, drought tolerance, forest trees
Classification (DDC)
630 Landwirtschaft, VeterinärmedizinSupplementary Research Data
https://doi.org/10.60507/FK2/AU4RUCKoch, Irmgard: The impact of water-soluble environmental aerosols on the drought tolerance of forest trees : a Germany-wide field study. - Bonn, 2026. - Dissertation, Rheinische Friedrich-Wilhelms-Universität Bonn.
Online-Ausgabe in bonndoc: https://nbn-resolving.org/urn:nbn:de:hbz:5-88374
Online-Ausgabe in bonndoc: https://nbn-resolving.org/urn:nbn:de:hbz:5-88374
@phdthesis{handle:20.500.11811/13935,
urn: https://nbn-resolving.org/urn:nbn:de:hbz:5-88374,
doi: https://doi.org/10.48565/bonndoc-800,
author = {{Irmgard Koch}},
title = {The impact of water-soluble environmental aerosols on the drought tolerance of forest trees : a Germany-wide field study},
school = {Rheinische Friedrich-Wilhelms-Universität Bonn},
year = 2026,
month = mar,
note = {Forest trees in Germany and around the world are showing increasing drought damage symptoms and higher mortality rates due to climate change. Trees suffer direct damage from drought periods and heat waves, and forest ecosystems are becoming less resilient, which increases the damage caused by biotic and abiotic factors. Hygroscopic aerosols could be another largely overlooked factor increasing drought stress in plants. Since the Industrial Revolution, aerosol pollution has increased significantly. Some of these aerosols are hygroscopic salts, that can draw moisture from the air and liquefy as a result (deliquescence). The HAS hypothesis (HAS: hydraulically activated stomata; Burkhardt, 2010) is a mechanistic model explaining the connection between hygroscopic salts and drought stress. According to the hypothesis, hygroscopic salts can activate stomata by forming a connection between the substomatal cavity and the leaf surface. Through this connection, liquid water can be transported in a bidirectional flow. This can lead to increased, uncontrollable water loss via the stomata.
The present study investigated the influence of deposited hygroscopic aerosol particles on the drought tolerance of forest trees. In this German-wide field study, leaves and needles of Fagus sylvatica (European beech), Quercus petraea (sessile oak), Pinus sylvestris (Scots pine), and Picea abies (Norway spruce) were sampled over a period of three years. Minimum epidermal conductance (gmin) and the water potential at turgor loss point (πTLP) were measured as indicators of drought tolerance. To determine hygroscopic aerosol deposition, the leaves and needles were washed, and the chemical composition of the wash solution was analyzed. The nutritional status of the leaves and needles and their nitrogen and carbon isotopic ratios were analyzed. The hydrophobicity of the surfaces was determined using contact angles. A greenhouse experiment compared needle and leaf surfaces with and without aerosols using electron microscopy and wax analysis.
The main novelty of this study is that significant correlations were found between the concentration of the washable ions and the drought tolerance parameters for each tree species, despite highly variable conditions. The existence of these significant correlations makes causal relationships likely, as they were established based on a mechanistic hypothesis and a targeted experimental approach.
In P. sylvestris, gmin and sodium were positively and significantly correlated. This supports the study's main hypothesis that aerosol deposition hydraulically activates stomata, thereby increasing gmin and reducing drought tolerance. This result corresponds with the filter approach to canopy interaction by Ulrich (1983), in which sodium does not interact with the leaf surfaces, allowing dry deposition to be inferred. For P. sylvestris, Ulrich's approach can also be used to explain the buffering of H3O+ by the base cations.
For the other tree species, a large number significant correlations between washable ions and gmin as well as πTLP were also recorded. These results are largely consistent with the HAS hypothesis, but in some cases new perspectives or assumptions regarding canopy interaction are necessary. Over the course of the year, the correlations demonstrate that HAS develops faster in Q. petraea than in P. sylvestris. Increased HAS and thus higher gmin then leads to more effective ion uptake, which also explains the significant negative correlations between the gmin and the ions. A rapid build-up of HAS can be advantageous for trees, as it enables them to absorb both nutrients and water through their stomata. The potentially functionally adapted leaf surfaces of tree species, combined with increasing atmospheric drought due to climate change and insufficiently strong reductions in air pollution, pose a drought risk for forests. The entire field of aerosol-plant interactions, should be investigated further, as it is important for both the nutrient and the water balance of trees.},
url = {https://hdl.handle.net/20.500.11811/13935}
}
urn: https://nbn-resolving.org/urn:nbn:de:hbz:5-88374,
doi: https://doi.org/10.48565/bonndoc-800,
author = {{Irmgard Koch}},
title = {The impact of water-soluble environmental aerosols on the drought tolerance of forest trees : a Germany-wide field study},
school = {Rheinische Friedrich-Wilhelms-Universität Bonn},
year = 2026,
month = mar,
note = {Forest trees in Germany and around the world are showing increasing drought damage symptoms and higher mortality rates due to climate change. Trees suffer direct damage from drought periods and heat waves, and forest ecosystems are becoming less resilient, which increases the damage caused by biotic and abiotic factors. Hygroscopic aerosols could be another largely overlooked factor increasing drought stress in plants. Since the Industrial Revolution, aerosol pollution has increased significantly. Some of these aerosols are hygroscopic salts, that can draw moisture from the air and liquefy as a result (deliquescence). The HAS hypothesis (HAS: hydraulically activated stomata; Burkhardt, 2010) is a mechanistic model explaining the connection between hygroscopic salts and drought stress. According to the hypothesis, hygroscopic salts can activate stomata by forming a connection between the substomatal cavity and the leaf surface. Through this connection, liquid water can be transported in a bidirectional flow. This can lead to increased, uncontrollable water loss via the stomata.
The present study investigated the influence of deposited hygroscopic aerosol particles on the drought tolerance of forest trees. In this German-wide field study, leaves and needles of Fagus sylvatica (European beech), Quercus petraea (sessile oak), Pinus sylvestris (Scots pine), and Picea abies (Norway spruce) were sampled over a period of three years. Minimum epidermal conductance (gmin) and the water potential at turgor loss point (πTLP) were measured as indicators of drought tolerance. To determine hygroscopic aerosol deposition, the leaves and needles were washed, and the chemical composition of the wash solution was analyzed. The nutritional status of the leaves and needles and their nitrogen and carbon isotopic ratios were analyzed. The hydrophobicity of the surfaces was determined using contact angles. A greenhouse experiment compared needle and leaf surfaces with and without aerosols using electron microscopy and wax analysis.
The main novelty of this study is that significant correlations were found between the concentration of the washable ions and the drought tolerance parameters for each tree species, despite highly variable conditions. The existence of these significant correlations makes causal relationships likely, as they were established based on a mechanistic hypothesis and a targeted experimental approach.
In P. sylvestris, gmin and sodium were positively and significantly correlated. This supports the study's main hypothesis that aerosol deposition hydraulically activates stomata, thereby increasing gmin and reducing drought tolerance. This result corresponds with the filter approach to canopy interaction by Ulrich (1983), in which sodium does not interact with the leaf surfaces, allowing dry deposition to be inferred. For P. sylvestris, Ulrich's approach can also be used to explain the buffering of H3O+ by the base cations.
For the other tree species, a large number significant correlations between washable ions and gmin as well as πTLP were also recorded. These results are largely consistent with the HAS hypothesis, but in some cases new perspectives or assumptions regarding canopy interaction are necessary. Over the course of the year, the correlations demonstrate that HAS develops faster in Q. petraea than in P. sylvestris. Increased HAS and thus higher gmin then leads to more effective ion uptake, which also explains the significant negative correlations between the gmin and the ions. A rapid build-up of HAS can be advantageous for trees, as it enables them to absorb both nutrients and water through their stomata. The potentially functionally adapted leaf surfaces of tree species, combined with increasing atmospheric drought due to climate change and insufficiently strong reductions in air pollution, pose a drought risk for forests. The entire field of aerosol-plant interactions, should be investigated further, as it is important for both the nutrient and the water balance of trees.},
url = {https://hdl.handle.net/20.500.11811/13935}
}
The following license files are associated with this item:
