The role of soil in defining planetary boundaries and the safe operating space for humanity

Department of Plant and Environmental Sciences

The role of soil in defining planetary boundaries and the safe operating space for humanity

Research output: Contribution to journal › Journal article › Research › peer-review

Standard

The role of soil in defining planetary boundaries and the safe operating space for humanity. / Kopittke, Peter M.; Menzies, Neal W.; Dalal, Ram C.; McKenna, Brigid A.; Husted, Søren; Wang, Peng; Lombi, Enzo.

In: Environment International, Vol. 146, 106245, 2021.

Research output: Contribution to journal › Journal article › Research › peer-review

Harvard

Kopittke, PM, Menzies, NW, Dalal, RC, McKenna, BA, Husted, S, Wang, P & Lombi, E 2021, 'The role of soil in defining planetary boundaries and the safe operating space for humanity', Environment International, vol. 146, 106245. https://doi.org/10.1016/j.envint.2020.106245

APA

Kopittke, P. M., Menzies, N. W., Dalal, R. C., McKenna, B. A., Husted, S., Wang, P., & Lombi, E. (2021). The role of soil in defining planetary boundaries and the safe operating space for humanity. Environment International, 146, [106245]. https://doi.org/10.1016/j.envint.2020.106245

Vancouver

Kopittke PM, Menzies NW, Dalal RC, McKenna BA, Husted S, Wang P et al. The role of soil in defining planetary boundaries and the safe operating space for humanity. Environment International. 2021;146. 106245. https://doi.org/10.1016/j.envint.2020.106245

Author

Kopittke, Peter M. ; Menzies, Neal W. ; Dalal, Ram C. ; McKenna, Brigid A. ; Husted, Søren ; Wang, Peng ; Lombi, Enzo. / The role of soil in defining planetary boundaries and the safe operating space for humanity. In: Environment International. 2021 ; Vol. 146.

Bibtex

@article{18db635025064ffd86d5d16c7b0fd1c2,

title = "The role of soil in defining planetary boundaries and the safe operating space for humanity",

abstract = "We use soils to provide 98.8% of our food, but we must ensure that the pressure we place on soils to provide this food in the short-term does not inadvertently push the Earth into a less hospitable state in the long-term. Using the planetary boundaries framework, we show that soils are a master variable for regulating critical Earth-system processes. Indeed, of the seven Earth-systems that have been quantified, soils play a critical and substantial role in changing the Earth-systems in at least two, either directly or indirectly, as well as smaller contributions for a further three. For the biogeochemical flows Earth-system process, soils contribute 66% of the total anthropogenic change for nitrogen and 38% for phosphorus, whilst for the land-system change Earth-system process, soils indirectly contribute 80% of global anthropogenic change. Furthermore, perturbations of soils contribute directly to 21% of climate change, 25% to ocean acidification, and 25% to stratospheric ozone depletion. We argue that urgent interventions are required to greatly improve soil management, especially for those Earth-system processes where the planetary boundary has already been exceeded and where soils make an important contribution, with this being for biogeochemical flows (both nitrogen and phosphorus), for climate change, and for land system change. Of particular importance, it is noted that the highly inefficient use of N fertilizers results in release of excess N into the broader environment, contributes to climate change, and results in release of ozone depleting substances. Furthermore, the use of soils for agricultural production results not only in land-system change, but also in the loss (mineralization) of organic matter with a concomitant release of CO2 contributing to both climate change and ocean acidification. Thus, there is a need to markedly improve the efficiency of fertilizer applications and to intensify usage of our most fertile soils in order to allow the restoration of degraded soils and limit further areal expansion of agriculture. Understanding, and acting upon, the role of soils is critical in ensuring that planetary boundaries are not transgressed, with no other single variable playing such a strategic role across all of the planetary boundaries.",

keywords = "Earth-system processes, Perturbation, Planetary boundaries, Soil, WATER-POLLUTION LEVELS, NITROUS-OXIDE N2O, FOOD SECURITY, CARBON, AGRICULTURE, PHOSPHORUS, BIODIVERSITY, LOADS",

author = "Kopittke, {Peter M.} and Menzies, {Neal W.} and Dalal, {Ram C.} and McKenna, {Brigid A.} and S{\o}ren Husted and Peng Wang and Enzo Lombi",

year = "2021",

doi = "10.1016/j.envint.2020.106245",

language = "English",

volume = "146",

journal = "Environment international",

issn = "0160-4120",

publisher = "Pergamon Press",

}

RIS

TY - JOUR

T1 - The role of soil in defining planetary boundaries and the safe operating space for humanity

AU - Kopittke, Peter M.

AU - Menzies, Neal W.

AU - Dalal, Ram C.

AU - McKenna, Brigid A.

AU - Husted, Søren

AU - Wang, Peng

AU - Lombi, Enzo

PY - 2021

Y1 - 2021

N2 - We use soils to provide 98.8% of our food, but we must ensure that the pressure we place on soils to provide this food in the short-term does not inadvertently push the Earth into a less hospitable state in the long-term. Using the planetary boundaries framework, we show that soils are a master variable for regulating critical Earth-system processes. Indeed, of the seven Earth-systems that have been quantified, soils play a critical and substantial role in changing the Earth-systems in at least two, either directly or indirectly, as well as smaller contributions for a further three. For the biogeochemical flows Earth-system process, soils contribute 66% of the total anthropogenic change for nitrogen and 38% for phosphorus, whilst for the land-system change Earth-system process, soils indirectly contribute 80% of global anthropogenic change. Furthermore, perturbations of soils contribute directly to 21% of climate change, 25% to ocean acidification, and 25% to stratospheric ozone depletion. We argue that urgent interventions are required to greatly improve soil management, especially for those Earth-system processes where the planetary boundary has already been exceeded and where soils make an important contribution, with this being for biogeochemical flows (both nitrogen and phosphorus), for climate change, and for land system change. Of particular importance, it is noted that the highly inefficient use of N fertilizers results in release of excess N into the broader environment, contributes to climate change, and results in release of ozone depleting substances. Furthermore, the use of soils for agricultural production results not only in land-system change, but also in the loss (mineralization) of organic matter with a concomitant release of CO2 contributing to both climate change and ocean acidification. Thus, there is a need to markedly improve the efficiency of fertilizer applications and to intensify usage of our most fertile soils in order to allow the restoration of degraded soils and limit further areal expansion of agriculture. Understanding, and acting upon, the role of soils is critical in ensuring that planetary boundaries are not transgressed, with no other single variable playing such a strategic role across all of the planetary boundaries.

AB - We use soils to provide 98.8% of our food, but we must ensure that the pressure we place on soils to provide this food in the short-term does not inadvertently push the Earth into a less hospitable state in the long-term. Using the planetary boundaries framework, we show that soils are a master variable for regulating critical Earth-system processes. Indeed, of the seven Earth-systems that have been quantified, soils play a critical and substantial role in changing the Earth-systems in at least two, either directly or indirectly, as well as smaller contributions for a further three. For the biogeochemical flows Earth-system process, soils contribute 66% of the total anthropogenic change for nitrogen and 38% for phosphorus, whilst for the land-system change Earth-system process, soils indirectly contribute 80% of global anthropogenic change. Furthermore, perturbations of soils contribute directly to 21% of climate change, 25% to ocean acidification, and 25% to stratospheric ozone depletion. We argue that urgent interventions are required to greatly improve soil management, especially for those Earth-system processes where the planetary boundary has already been exceeded and where soils make an important contribution, with this being for biogeochemical flows (both nitrogen and phosphorus), for climate change, and for land system change. Of particular importance, it is noted that the highly inefficient use of N fertilizers results in release of excess N into the broader environment, contributes to climate change, and results in release of ozone depleting substances. Furthermore, the use of soils for agricultural production results not only in land-system change, but also in the loss (mineralization) of organic matter with a concomitant release of CO2 contributing to both climate change and ocean acidification. Thus, there is a need to markedly improve the efficiency of fertilizer applications and to intensify usage of our most fertile soils in order to allow the restoration of degraded soils and limit further areal expansion of agriculture. Understanding, and acting upon, the role of soils is critical in ensuring that planetary boundaries are not transgressed, with no other single variable playing such a strategic role across all of the planetary boundaries.

KW - Earth-system processes

KW - Perturbation

KW - Planetary boundaries

KW - Soil

KW - WATER-POLLUTION LEVELS

KW - NITROUS-OXIDE N2O

KW - FOOD SECURITY

KW - CARBON

KW - AGRICULTURE

KW - PHOSPHORUS

KW - BIODIVERSITY

KW - LOADS

U2 - 10.1016/j.envint.2020.106245

DO - 10.1016/j.envint.2020.106245

M3 - Journal article

C2 - 33161202

VL - 146

JO - Environment international

JF - Environment international

SN - 0160-4120

M1 - 106245

ER -

ID: 255459223