Influence of long-term phosphorus fertilisation history on the availability and chemical nature of soil phosphorus

Department of Plant and Environmental Sciences

Influence of long-term phosphorus fertilisation history on the availability and chemical nature of soil phosphorus

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

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Influence of long-term phosphorus fertilisation history on the availability and chemical nature of soil phosphorus. / van der Bom, F. J.T.; McLaren, T. I.; Doolette, A. L.; Magid, J.; Frossard, E.; Oberson, A.; Jensen, L. S.

In: Geoderma, Vol. 355, 113909, 01.12.2019, p. 1-12.

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

Harvard

van der Bom, FJT, McLaren, TI, Doolette, AL, Magid, J, Frossard, E, Oberson, A & Jensen, LS 2019, 'Influence of long-term phosphorus fertilisation history on the availability and chemical nature of soil phosphorus', Geoderma, vol. 355, 113909, pp. 1-12. https://doi.org/10.1016/j.geoderma.2019.113909

APA

van der Bom, F. J. T., McLaren, T. I., Doolette, A. L., Magid, J., Frossard, E., Oberson, A., & Jensen, L. S. (2019). Influence of long-term phosphorus fertilisation history on the availability and chemical nature of soil phosphorus. Geoderma, 355, 1-12. [113909]. https://doi.org/10.1016/j.geoderma.2019.113909

Vancouver

van der Bom FJT, McLaren TI, Doolette AL, Magid J, Frossard E, Oberson A et al. Influence of long-term phosphorus fertilisation history on the availability and chemical nature of soil phosphorus. Geoderma. 2019 Dec 1;355:1-12. 113909. https://doi.org/10.1016/j.geoderma.2019.113909

Author

van der Bom, F. J.T. ; McLaren, T. I. ; Doolette, A. L. ; Magid, J. ; Frossard, E. ; Oberson, A. ; Jensen, L. S. / Influence of long-term phosphorus fertilisation history on the availability and chemical nature of soil phosphorus. In: Geoderma. 2019 ; Vol. 355. pp. 1-12.

Bibtex

@article{0380bc6dc94647c39141acf855fd0f6b,

title = "Influence of long-term phosphorus fertilisation history on the availability and chemical nature of soil phosphorus",

abstract = "Data on the dynamics and fate of phosphorus (P) under low soil-test P (STP) conditions is essential for the development of cropping strategies with a high P use efficiency. This study examined the effects of long-term (20 years) mineral and organic fertiliser P applications on a P-depleted sandy loam soil in Denmark. The cycling of P was examined by use of P budgets (inputs-offtake), chemical P extractions, 33P isotopic exchange kinetics (IEK), and solution 31P nuclear magnetic resonance (NMR) spectroscopy on NaOH-EDTA extracts. Recovery of applied P in the topsoil was smaller for animal slurry P compared with mineral fertiliser P. The budgets suggest deeper soil layers play an important role for the cycling of P. Resin-extractable P (2 to 17 mg kg−1), Olsen-P (7 to 16 mg kg−1) and E1min (1 to 6 mg kg−1) were correlated with the P budgets. Between 63 and 77% of total inorganic P was not exchangeable in a period of three months (E>3months), with the lowest value observed in no-P treatment N1K1. The data show that a redistribution of exchangeable P had taken place under the influence of a strongly negative P budget. Microbial P (6 to 18 mg kg−1) increased under animal slurry inputs compared with mineral fertiliser applications (p < 0.05). All soils were dominated by phosphomonoesters and orthophosphate (98 to 99% of the NMR signal). Concentrations of orthophosphate (86 to 135 mg kg−1) varied significantly between treatments (p < 0.01), whereas forms of organic P remained largely unchanged. The results demonstrate that P applications increased the amount of P that is potentially available for plants, irrespective of input form. Nevertheless, most P applied in excess of crop uptake resulted in an increase of the amount of P that is slowly exchangeable. Under low soil test P conditions such as in the current trial, fertiliser P applied in excess of plant demand that accumulates in soil would thus only be partially available for crops in subsequent years. On the other hand the data suggests that soil P reserves may be utilised for crop growth, but at the low soil P intensity plant access to P will have to be managed carefully.",

keywords = "P NMR spectroscopy, P isotopic exchange kinetics, Microbial phosphorus, Phosphorus depletion, Phosphorus dynamics",

author = "{van der Bom}, {F. J.T.} and McLaren, {T. I.} and Doolette, {A. L.} and J. Magid and E. Frossard and A. Oberson and Jensen, {L. S.}",

year = "2019",

month = dec,

day = "1",

doi = "10.1016/j.geoderma.2019.113909",

language = "English",

volume = "355",

pages = "1--12",

journal = "Geoderma",

issn = "0016-7061",

publisher = "Elsevier",

}

RIS

TY - JOUR

T1 - Influence of long-term phosphorus fertilisation history on the availability and chemical nature of soil phosphorus

AU - van der Bom, F. J.T.

AU - McLaren, T. I.

AU - Doolette, A. L.

AU - Magid, J.

AU - Frossard, E.

AU - Oberson, A.

AU - Jensen, L. S.

PY - 2019/12/1

Y1 - 2019/12/1

N2 - Data on the dynamics and fate of phosphorus (P) under low soil-test P (STP) conditions is essential for the development of cropping strategies with a high P use efficiency. This study examined the effects of long-term (20 years) mineral and organic fertiliser P applications on a P-depleted sandy loam soil in Denmark. The cycling of P was examined by use of P budgets (inputs-offtake), chemical P extractions, 33P isotopic exchange kinetics (IEK), and solution 31P nuclear magnetic resonance (NMR) spectroscopy on NaOH-EDTA extracts. Recovery of applied P in the topsoil was smaller for animal slurry P compared with mineral fertiliser P. The budgets suggest deeper soil layers play an important role for the cycling of P. Resin-extractable P (2 to 17 mg kg−1), Olsen-P (7 to 16 mg kg−1) and E1min (1 to 6 mg kg−1) were correlated with the P budgets. Between 63 and 77% of total inorganic P was not exchangeable in a period of three months (E>3months), with the lowest value observed in no-P treatment N1K1. The data show that a redistribution of exchangeable P had taken place under the influence of a strongly negative P budget. Microbial P (6 to 18 mg kg−1) increased under animal slurry inputs compared with mineral fertiliser applications (p < 0.05). All soils were dominated by phosphomonoesters and orthophosphate (98 to 99% of the NMR signal). Concentrations of orthophosphate (86 to 135 mg kg−1) varied significantly between treatments (p < 0.01), whereas forms of organic P remained largely unchanged. The results demonstrate that P applications increased the amount of P that is potentially available for plants, irrespective of input form. Nevertheless, most P applied in excess of crop uptake resulted in an increase of the amount of P that is slowly exchangeable. Under low soil test P conditions such as in the current trial, fertiliser P applied in excess of plant demand that accumulates in soil would thus only be partially available for crops in subsequent years. On the other hand the data suggests that soil P reserves may be utilised for crop growth, but at the low soil P intensity plant access to P will have to be managed carefully.

AB - Data on the dynamics and fate of phosphorus (P) under low soil-test P (STP) conditions is essential for the development of cropping strategies with a high P use efficiency. This study examined the effects of long-term (20 years) mineral and organic fertiliser P applications on a P-depleted sandy loam soil in Denmark. The cycling of P was examined by use of P budgets (inputs-offtake), chemical P extractions, 33P isotopic exchange kinetics (IEK), and solution 31P nuclear magnetic resonance (NMR) spectroscopy on NaOH-EDTA extracts. Recovery of applied P in the topsoil was smaller for animal slurry P compared with mineral fertiliser P. The budgets suggest deeper soil layers play an important role for the cycling of P. Resin-extractable P (2 to 17 mg kg−1), Olsen-P (7 to 16 mg kg−1) and E1min (1 to 6 mg kg−1) were correlated with the P budgets. Between 63 and 77% of total inorganic P was not exchangeable in a period of three months (E>3months), with the lowest value observed in no-P treatment N1K1. The data show that a redistribution of exchangeable P had taken place under the influence of a strongly negative P budget. Microbial P (6 to 18 mg kg−1) increased under animal slurry inputs compared with mineral fertiliser applications (p < 0.05). All soils were dominated by phosphomonoesters and orthophosphate (98 to 99% of the NMR signal). Concentrations of orthophosphate (86 to 135 mg kg−1) varied significantly between treatments (p < 0.01), whereas forms of organic P remained largely unchanged. The results demonstrate that P applications increased the amount of P that is potentially available for plants, irrespective of input form. Nevertheless, most P applied in excess of crop uptake resulted in an increase of the amount of P that is slowly exchangeable. Under low soil test P conditions such as in the current trial, fertiliser P applied in excess of plant demand that accumulates in soil would thus only be partially available for crops in subsequent years. On the other hand the data suggests that soil P reserves may be utilised for crop growth, but at the low soil P intensity plant access to P will have to be managed carefully.

KW - P NMR spectroscopy

KW - P isotopic exchange kinetics

KW - Microbial phosphorus

KW - Phosphorus depletion

KW - Phosphorus dynamics

U2 - 10.1016/j.geoderma.2019.113909

DO - 10.1016/j.geoderma.2019.113909

M3 - Journal article

AN - SCOPUS:85070662907

VL - 355

SP - 1

EP - 12

JO - Geoderma

JF - Geoderma

SN - 0016-7061

M1 - 113909

ER -

ID: 234148871