Details
Originalsprache | Englisch |
---|---|
Seiten (von - bis) | 1076-1085 |
Seitenumfang | 10 |
Fachzeitschrift | Science of the Total Environment |
Jahrgang | 568 |
Frühes Online-Datum | 30 Juni 2016 |
Publikationsstatus | Veröffentlicht - 15 Okt. 2016 |
Extern publiziert | Ja |
Abstract
Soils are faced with man-made chemical stress factors, such as the input of organic or metal-containing pesticides, in combination with non-chemical stressors like soil compaction and natural disturbance like drought. Although multiple stress factors are typically co-occurring in soil ecosystems, research in soil sciences on this aspect is limited and focuses mostly on single structural or functional endpoints. A mechanistic understanding of the reaction of soils to multiple stressors is currently lacking. Based on a review of resilience theory, we introduce a new concept for research on the ability of polluted soil (xenobiotics or other chemical pollutants as one stressor) to resist further natural or anthropogenic stress and to retain its functions and structure. There is strong indication that pollution as a primary stressor will change the system reaction of soil, i.e., its resilience, stability and resistance. It can be expected that pollution affects the physiological adaption of organisms and the functional redundancy of the soil to further stress. We hypothesize that the recovery of organisms and chemical-physical properties after impact of a follow-up stressor is faster in polluted soil than in non-polluted soil, i.e., polluted soil has a higher dynamical stability (dynamical stability = 1 / recovery time), whereas resilience of the contaminated soil is lower compared to that of not or less contaminated soil. Thus, a polluted soil might be more prone to change into another system regime after occurrence of further stress. We highlight this issue by compiling the literature exemplarily for the effects of Cu contamination and compaction on soil functions and structure. We propose to intensify research on effects of combined stresses involving a multidisciplinary team of experts and provide suggestions for corresponding experiments. Our concept offers thus a framework for system level analysis of soils paving the way to enhance ecological theory.
ASJC Scopus Sachgebiete
- Umweltwissenschaften (insg.)
- Environmental engineering
- Umweltwissenschaften (insg.)
- Umweltchemie
- Umweltwissenschaften (insg.)
- Abfallwirtschaft und -entsorgung
- Umweltwissenschaften (insg.)
- Umweltverschmutzung
Ziele für nachhaltige Entwicklung
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in: Science of the Total Environment, Jahrgang 568, 15.10.2016, S. 1076-1085.
Publikation: Beitrag in Fachzeitschrift › Meinungsbeitrag › Forschung › Peer-Review
}
TY - JOUR
T1 - The impact of chemical pollution on the resilience of soils under multiple stresses
T2 - A conceptual framework for future research
AU - Schaeffer, Andreas
AU - Amelung, Wulf
AU - Hollert, Henner
AU - Kaestner, Matthias
AU - Kandeler, Ellen
AU - Kruse, Jens
AU - Miltner, Anja
AU - Ottermanns, Richard
AU - Pagel, Holger
AU - Peth, Stephan
AU - Poll, Christian
AU - Rambold, Gerhard
AU - Schloter, Michael
AU - Schulz, Stefanie
AU - Streck, Thilo
AU - Roß-Nickoll, Martina
N1 - Publisher Copyright: © 2016 Elsevier B.V.
PY - 2016/10/15
Y1 - 2016/10/15
N2 - Soils are faced with man-made chemical stress factors, such as the input of organic or metal-containing pesticides, in combination with non-chemical stressors like soil compaction and natural disturbance like drought. Although multiple stress factors are typically co-occurring in soil ecosystems, research in soil sciences on this aspect is limited and focuses mostly on single structural or functional endpoints. A mechanistic understanding of the reaction of soils to multiple stressors is currently lacking. Based on a review of resilience theory, we introduce a new concept for research on the ability of polluted soil (xenobiotics or other chemical pollutants as one stressor) to resist further natural or anthropogenic stress and to retain its functions and structure. There is strong indication that pollution as a primary stressor will change the system reaction of soil, i.e., its resilience, stability and resistance. It can be expected that pollution affects the physiological adaption of organisms and the functional redundancy of the soil to further stress. We hypothesize that the recovery of organisms and chemical-physical properties after impact of a follow-up stressor is faster in polluted soil than in non-polluted soil, i.e., polluted soil has a higher dynamical stability (dynamical stability = 1 / recovery time), whereas resilience of the contaminated soil is lower compared to that of not or less contaminated soil. Thus, a polluted soil might be more prone to change into another system regime after occurrence of further stress. We highlight this issue by compiling the literature exemplarily for the effects of Cu contamination and compaction on soil functions and structure. We propose to intensify research on effects of combined stresses involving a multidisciplinary team of experts and provide suggestions for corresponding experiments. Our concept offers thus a framework for system level analysis of soils paving the way to enhance ecological theory.
AB - Soils are faced with man-made chemical stress factors, such as the input of organic or metal-containing pesticides, in combination with non-chemical stressors like soil compaction and natural disturbance like drought. Although multiple stress factors are typically co-occurring in soil ecosystems, research in soil sciences on this aspect is limited and focuses mostly on single structural or functional endpoints. A mechanistic understanding of the reaction of soils to multiple stressors is currently lacking. Based on a review of resilience theory, we introduce a new concept for research on the ability of polluted soil (xenobiotics or other chemical pollutants as one stressor) to resist further natural or anthropogenic stress and to retain its functions and structure. There is strong indication that pollution as a primary stressor will change the system reaction of soil, i.e., its resilience, stability and resistance. It can be expected that pollution affects the physiological adaption of organisms and the functional redundancy of the soil to further stress. We hypothesize that the recovery of organisms and chemical-physical properties after impact of a follow-up stressor is faster in polluted soil than in non-polluted soil, i.e., polluted soil has a higher dynamical stability (dynamical stability = 1 / recovery time), whereas resilience of the contaminated soil is lower compared to that of not or less contaminated soil. Thus, a polluted soil might be more prone to change into another system regime after occurrence of further stress. We highlight this issue by compiling the literature exemplarily for the effects of Cu contamination and compaction on soil functions and structure. We propose to intensify research on effects of combined stresses involving a multidisciplinary team of experts and provide suggestions for corresponding experiments. Our concept offers thus a framework for system level analysis of soils paving the way to enhance ecological theory.
KW - Compaction
KW - Copper
KW - Natural stress
KW - Pollutants
KW - Resilience
KW - Resistance
KW - Stability
UR - http://www.scopus.com/inward/record.url?scp=84978383981&partnerID=8YFLogxK
U2 - 10.1016/j.scitotenv.2016.06.161
DO - 10.1016/j.scitotenv.2016.06.161
M3 - Comment/debate
AN - SCOPUS:84978383981
VL - 568
SP - 1076
EP - 1085
JO - Science of the Total Environment
JF - Science of the Total Environment
SN - 0048-9697
ER -