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A computational history and outlook of nitrogen use efficiency and precipitation-optimal fertilisation timings in agriculture

A computational history and outlook of nitrogen use efficiency and precipitation-optimal fertilisation timings in agriculture
A computational history and outlook of nitrogen use efficiency and precipitation-optimal fertilisation timings in agriculture
Half of the nitrogen applied to arable-fields is lost through several processes linked to soil moisture. Low soil moisture limits nitrogen mobility reducing nitrogen-uptake while wetter conditions can increase nitrogen leaching. Rainfall ultimately governs soil moisture and the fate of nitrogen in soil. However, the interaction between rainfall and nitrogen use efficiency (NUE) remains poorly understood.
We developed a field-scale modelling platform that describes coupled water and nitrogen transport, root growth and uptake, rainfall, the nitrogen-cycle and leaching to assess the NUE of split fertilisations with realistic rainfall patterns. The model was solved for every possible split fertilisation timing in 200+ growing seasons to determine optimal timings. Two previous field trials regarding rainfall and NUE had contrasting results: wetter years have enhanced fertiliser loss and drier years reduced plant nitrogen uptake. By choosing appropriate fertilisation timings in the model we could recreate the two contrasting trends and maintain variability in the data. However, we found by choosing other fertilisation timings we could mitigate the leaching in wetter years. Optimised timings could increase plant nitrogen uptake by up to 35% compared to the mean in dry years. Plant uptake was greatest under drier conditions due to mitigated leaching, but less likely to occur due to low nitrogen mobility. Optimal fertilisation timings varied dramatically depending on the rainfall patterns. Historic and projected rainfall patterns from 1950-2069 were used in the model. We found optimal NUE has a decrease from 2022-2040 due to increased heavy rainfall events and optimal fertilisation timings are later in the season but varied largely on a season-to-season basis.
The results are a step towards achieving improved nitrogen efficiency in agriculture by using the ‘at the right time’ agronomic-strategy in the ‘4Rs’ of improved nitrogen fertilisation. Our results can help determine nitrogen fertilisation timings in changing climates.
33
Mckay Fletcher, Daniel
db06e7e0-69af-4fa2-89b3-26f6599e43d4
Ruiz, Siul Aljadi
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Dias, T.
f1d6edfe-d128-4c37-9312-fafcf81d929c
Williams, Katherine
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Petroselli, Chiara
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Walker, Nancy, Catherine
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Chadwick, D.
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Jones, D. L.
aa75a0d9-20c3-4c0e-a986-10bb4185321d
Roose, Tiina
3581ab5b-71e1-4897-8d88-59f13f3bccfe
Mckay Fletcher, Daniel
db06e7e0-69af-4fa2-89b3-26f6599e43d4
Ruiz, Siul Aljadi
d79b3b82-7c0d-47cc-9616-11d29e6a41bd
Dias, T.
f1d6edfe-d128-4c37-9312-fafcf81d929c
Williams, Katherine
bf87a040-9a95-4c4e-a078-d289404b7523
Petroselli, Chiara
19266726-2dc0-4790-af77-7ccdc45865eb
Walker, Nancy, Catherine
0b539663-b1db-4e93-a513-2580c3229df4
Chadwick, D.
0d8261cf-be5f-44cc-8afb-baa7fe4def3c
Jones, D. L.
aa75a0d9-20c3-4c0e-a986-10bb4185321d
Roose, Tiina
3581ab5b-71e1-4897-8d88-59f13f3bccfe

Mckay Fletcher, Daniel, Ruiz, Siul Aljadi, Dias, T., Williams, Katherine, Petroselli, Chiara, Walker, Nancy, Catherine, Chadwick, D., Jones, D. L. and Roose, Tiina (2021) A computational history and outlook of nitrogen use efficiency and precipitation-optimal fertilisation timings in agriculture. 3rd ISMC Conference, Online, United Kingdom. 18 - 22 May 2021. p. 33 . (doi:10.5194/ismc2021-11).

Record type: Conference or Workshop Item (Paper)

Abstract

Half of the nitrogen applied to arable-fields is lost through several processes linked to soil moisture. Low soil moisture limits nitrogen mobility reducing nitrogen-uptake while wetter conditions can increase nitrogen leaching. Rainfall ultimately governs soil moisture and the fate of nitrogen in soil. However, the interaction between rainfall and nitrogen use efficiency (NUE) remains poorly understood.
We developed a field-scale modelling platform that describes coupled water and nitrogen transport, root growth and uptake, rainfall, the nitrogen-cycle and leaching to assess the NUE of split fertilisations with realistic rainfall patterns. The model was solved for every possible split fertilisation timing in 200+ growing seasons to determine optimal timings. Two previous field trials regarding rainfall and NUE had contrasting results: wetter years have enhanced fertiliser loss and drier years reduced plant nitrogen uptake. By choosing appropriate fertilisation timings in the model we could recreate the two contrasting trends and maintain variability in the data. However, we found by choosing other fertilisation timings we could mitigate the leaching in wetter years. Optimised timings could increase plant nitrogen uptake by up to 35% compared to the mean in dry years. Plant uptake was greatest under drier conditions due to mitigated leaching, but less likely to occur due to low nitrogen mobility. Optimal fertilisation timings varied dramatically depending on the rainfall patterns. Historic and projected rainfall patterns from 1950-2069 were used in the model. We found optimal NUE has a decrease from 2022-2040 due to increased heavy rainfall events and optimal fertilisation timings are later in the season but varied largely on a season-to-season basis.
The results are a step towards achieving improved nitrogen efficiency in agriculture by using the ‘at the right time’ agronomic-strategy in the ‘4Rs’ of improved nitrogen fertilisation. Our results can help determine nitrogen fertilisation timings in changing climates.

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More information

Published date: 22 May 2021
Venue - Dates: 3rd ISMC Conference, Online, United Kingdom, 2021-05-18 - 2021-05-22

Identifiers

Local EPrints ID: 467557
URI: http://eprints.soton.ac.uk/id/eprint/467557
PURE UUID: 970b540d-7f43-47bf-b407-48b8b8a57d2f
ORCID for Daniel Mckay Fletcher: ORCID iD orcid.org/0000-0001-6569-2931
ORCID for Katherine Williams: ORCID iD orcid.org/0000-0001-6827-9261
ORCID for Nancy, Catherine Walker: ORCID iD orcid.org/0000-0003-2297-1046
ORCID for Tiina Roose: ORCID iD orcid.org/0000-0001-8710-1063

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Date deposited: 13 Jul 2022 17:09
Last modified: 04 Jun 2024 01:57

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Contributors

Author: Daniel Mckay Fletcher ORCID iD
Author: T. Dias
Author: Katherine Williams ORCID iD
Author: Chiara Petroselli
Author: D. Chadwick
Author: D. L. Jones
Author: Tiina Roose ORCID iD

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