Combining spectroscopic and isotopic techniques gives a dynamic view of phosphorus cycling in soil

Julian Helfenstein; Federica Tamburini; Christian von Sperber; Michael S. Massey; Chiara Pistocchi; Oliver A. Chadwick; Peter M. Vitousek; Ruben Kretzschmar; Emmanuel Frossard

doi:10.1038/s41467-018-05731-2

Combining spectroscopic and isotopic techniques gives a dynamic view of phosphorus cycling in soil

Julian Helfenstein^*, Federica Tamburini, Christian von Sperber, Michael S. Massey, Chiara Pistocchi, Oliver A. Chadwick, Peter M. Vitousek, Ruben Kretzschmar, Emmanuel Frossard

^*Corresponding author for this work

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

175 Citations (Scopus)

Abstract

Current understanding of phosphorus (P) cycling in soils can be enhanced by integrating previously discrete findings concerning P speciation, exchange kinetics, and the underlying biological and geochemical processes. Here, we combine sequential extraction with P K-edge X-ray absorption spectroscopy and isotopic methods (³³P and ¹⁸O in phosphate) to characterize P cycling on a climatic gradient in Hawaii. We link P pools to P species and estimate the turnover times for commonly considered P pools. Dissolved P turned over in seconds, resin-extractable P in minutes, NaOH-extractable inorganic P in weeks to months, and HCl-extractable P in years to millennia. Furthermore, we show that in arid-zone soils, some primary mineral P remains even after 150 ky of soil development, whereas in humid-zone soils of the same age, all P in all pools has been biologically cycled. The integrative information we provide makes possible a more dynamic, process-oriented conceptual model of P cycling in soils.

Original language	English
Article number	3226
Journal	Nature Communications
Volume	9
Issue number	1
DOIs	https://doi.org/10.1038/s41467-018-05731-2
Publication status	Published - 13 Aug 2018
Externally published	Yes

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title = "Combining spectroscopic and isotopic techniques gives a dynamic view of phosphorus cycling in soil",

abstract = "Current understanding of phosphorus (P) cycling in soils can be enhanced by integrating previously discrete findings concerning P speciation, exchange kinetics, and the underlying biological and geochemical processes. Here, we combine sequential extraction with P K-edge X-ray absorption spectroscopy and isotopic methods (33P and 18O in phosphate) to characterize P cycling on a climatic gradient in Hawaii. We link P pools to P species and estimate the turnover times for commonly considered P pools. Dissolved P turned over in seconds, resin-extractable P in minutes, NaOH-extractable inorganic P in weeks to months, and HCl-extractable P in years to millennia. Furthermore, we show that in arid-zone soils, some primary mineral P remains even after 150 ky of soil development, whereas in humid-zone soils of the same age, all P in all pools has been biologically cycled. The integrative information we provide makes possible a more dynamic, process-oriented conceptual model of P cycling in soils.",

author = "Julian Helfenstein and Federica Tamburini and {von Sperber}, Christian and Massey, {Michael S.} and Chiara Pistocchi and Chadwick, {Oliver A.} and Vitousek, {Peter M.} and Ruben Kretzschmar and Emmanuel Frossard",

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AU - Helfenstein, Julian

AU - Tamburini, Federica

AU - von Sperber, Christian

AU - Massey, Michael S.

AU - Pistocchi, Chiara

AU - Chadwick, Oliver A.

AU - Vitousek, Peter M.

AU - Kretzschmar, Ruben

AU - Frossard, Emmanuel

PY - 2018/8/13

Y1 - 2018/8/13

N2 - Current understanding of phosphorus (P) cycling in soils can be enhanced by integrating previously discrete findings concerning P speciation, exchange kinetics, and the underlying biological and geochemical processes. Here, we combine sequential extraction with P K-edge X-ray absorption spectroscopy and isotopic methods (33P and 18O in phosphate) to characterize P cycling on a climatic gradient in Hawaii. We link P pools to P species and estimate the turnover times for commonly considered P pools. Dissolved P turned over in seconds, resin-extractable P in minutes, NaOH-extractable inorganic P in weeks to months, and HCl-extractable P in years to millennia. Furthermore, we show that in arid-zone soils, some primary mineral P remains even after 150 ky of soil development, whereas in humid-zone soils of the same age, all P in all pools has been biologically cycled. The integrative information we provide makes possible a more dynamic, process-oriented conceptual model of P cycling in soils.

AB - Current understanding of phosphorus (P) cycling in soils can be enhanced by integrating previously discrete findings concerning P speciation, exchange kinetics, and the underlying biological and geochemical processes. Here, we combine sequential extraction with P K-edge X-ray absorption spectroscopy and isotopic methods (33P and 18O in phosphate) to characterize P cycling on a climatic gradient in Hawaii. We link P pools to P species and estimate the turnover times for commonly considered P pools. Dissolved P turned over in seconds, resin-extractable P in minutes, NaOH-extractable inorganic P in weeks to months, and HCl-extractable P in years to millennia. Furthermore, we show that in arid-zone soils, some primary mineral P remains even after 150 ky of soil development, whereas in humid-zone soils of the same age, all P in all pools has been biologically cycled. The integrative information we provide makes possible a more dynamic, process-oriented conceptual model of P cycling in soils.

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Combining spectroscopic and isotopic techniques gives a dynamic view of phosphorus cycling in soil

Abstract

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