Combining automated and manual chambers to provide reliable estimates of N2O emissions in annual and perennial cropping systems

Imran Ahammad Siddique; Diego Abalos; Johannes Wilhelmus Maria Pullens; Klaus Steenberg Larsen; Uffe Jørgensen; Poul Erik Lærke

doi:10.1016/j.agrformet.2025.110530

Combining automated and manual chambers to provide reliable estimates of N₂O emissions in annual and perennial cropping systems

Imran Ahammad Siddique^*, Diego Abalos, Johannes Wilhelmus Maria Pullens, Klaus Steenberg Larsen, Uffe Jørgensen, Poul Erik Lærke

^*Corresponding author for this work

Research output: Contribution to journal/Conference contribution in journal/Contribution to newspaper › Journal article › Research › peer-review

Abstract

Perennials can produce more biomass and partially replace annual crops. However, environmental benefits of perennials over annuals in terms of nitrous oxide (N₂O) emissions have rarely been compared in a long-term field experiment. By combining automatic and manual chamber methods, we aimed to develop reliable N₂O estimates from annual and perennial systems. We measured N₂O emissions from: i. perennial grass during renovation including spring barley as catch crop (SB/RG); ii. perennial grass-clover mixture (GC); iii. triticale monoculture (Trit). Results showed that cumulative N₂O emissions from SB/RG were higher than GC or Trit. The highest emission rate was measured for SB/RG (258.9 µg N₂O[sbnd]N m^-2 h^-1) after fertilization in spring. Increased N₂O emissions were also seen for a short period after direct grass seeding in August. For Trit, N₂O emissions increased after fertilization in March and ploughing in late September. In GC (fertilized with P and K), there was no N₂O peak after grass cutting. Both from manual and automatic chamber systems, “hot moments” of N₂O emissions contributed ∼16–79 % of cumulative emissions. By predicting hot moments and scheduling frequent measurements, manual chambers captured most of the N₂O dynamics. The results indicated that the hot moments of N₂O emissions were better quantified by automatic chambers, while some of the hot moments, for instance, fertilization and ploughing in Trit were accurately captured with manual chambers. Soil nitrate and ammonium were positively associated with N₂O emissions, whereas biomass N uptake was negatively associated. We conclude that perennial (GC) is a promising system for high biomass production with low environmental impact. Strategies such as growing spring barley as a catch crop, grass seeding with shallow tillage, and fertilization of newly seeded grass matching crop N demand are needed to reduce the higher risk for N losses.

Original language	English
Article number	110530
Journal	Agricultural and Forest Meteorology
Volume	367
ISSN	0168-1923
DOIs	https://doi.org/10.1016/j.agrformet.2025.110530
Publication status	Published - May 2025

Keywords

Biomass n uptake
Grass-clover
Grassland renovation
Long-term site

Access to Document

10.1016/j.agrformet.2025.110530Licence: CC BY

Cite this

@article{9bdeabddf5134958be3f7f66d0f93efb,

title = "Combining automated and manual chambers to provide reliable estimates of N2O emissions in annual and perennial cropping systems",

abstract = "Perennials can produce more biomass and partially replace annual crops. However, environmental benefits of perennials over annuals in terms of nitrous oxide (N2O) emissions have rarely been compared in a long-term field experiment. By combining automatic and manual chamber methods, we aimed to develop reliable N2O estimates from annual and perennial systems. We measured N2O emissions from: i. perennial grass during renovation including spring barley as catch crop (SB/RG); ii. perennial grass-clover mixture (GC); iii. triticale monoculture (Trit). Results showed that cumulative N2O emissions from SB/RG were higher than GC or Trit. The highest emission rate was measured for SB/RG (258.9 µg N2O[sbnd]N m-2 h-1) after fertilization in spring. Increased N2O emissions were also seen for a short period after direct grass seeding in August. For Trit, N2O emissions increased after fertilization in March and ploughing in late September. In GC (fertilized with P and K), there was no N2O peak after grass cutting. Both from manual and automatic chamber systems, “hot moments” of N2O emissions contributed ∼16–79 % of cumulative emissions. By predicting hot moments and scheduling frequent measurements, manual chambers captured most of the N2O dynamics. The results indicated that the hot moments of N2O emissions were better quantified by automatic chambers, while some of the hot moments, for instance, fertilization and ploughing in Trit were accurately captured with manual chambers. Soil nitrate and ammonium were positively associated with N2O emissions, whereas biomass N uptake was negatively associated. We conclude that perennial (GC) is a promising system for high biomass production with low environmental impact. Strategies such as growing spring barley as a catch crop, grass seeding with shallow tillage, and fertilization of newly seeded grass matching crop N demand are needed to reduce the higher risk for N losses.",

keywords = "Biomass n uptake, Grass-clover, Grassland renovation, Long-term site",

author = "Siddique, {Imran Ahammad} and Diego Abalos and Pullens, {Johannes Wilhelmus Maria} and Larsen, {Klaus Steenberg} and Uffe J{\o}rgensen and L{\ae}rke, {Poul Erik}",

note = "Publisher Copyright: {\textcopyright} 2025 The Author(s)",

year = "2025",

month = may,

doi = "10.1016/j.agrformet.2025.110530",

language = "English",

volume = "367",

journal = "Agricultural and Forest Meteorology",

issn = "0168-1923",

publisher = "Elsevier B.V.",

}

Combining automated and manual chambers to provide reliable estimates of N₂O emissions in annual and perennial cropping systems. / Siddique, Imran Ahammad ; Abalos, Diego ; Pullens, Johannes Wilhelmus Maria et al.
In: Agricultural and Forest Meteorology, Vol. 367, 110530, 05.2025.

Research output: Contribution to journal/Conference contribution in journal/Contribution to newspaper › Journal article › Research › peer-review

TY - JOUR

T1 - Combining automated and manual chambers to provide reliable estimates of N2O emissions in annual and perennial cropping systems

AU - Siddique, Imran Ahammad

AU - Abalos, Diego

AU - Pullens, Johannes Wilhelmus Maria

AU - Larsen, Klaus Steenberg

AU - Jørgensen, Uffe

AU - Lærke, Poul Erik

PY - 2025/5

Y1 - 2025/5

N2 - Perennials can produce more biomass and partially replace annual crops. However, environmental benefits of perennials over annuals in terms of nitrous oxide (N2O) emissions have rarely been compared in a long-term field experiment. By combining automatic and manual chamber methods, we aimed to develop reliable N2O estimates from annual and perennial systems. We measured N2O emissions from: i. perennial grass during renovation including spring barley as catch crop (SB/RG); ii. perennial grass-clover mixture (GC); iii. triticale monoculture (Trit). Results showed that cumulative N2O emissions from SB/RG were higher than GC or Trit. The highest emission rate was measured for SB/RG (258.9 µg N2O[sbnd]N m-2 h-1) after fertilization in spring. Increased N2O emissions were also seen for a short period after direct grass seeding in August. For Trit, N2O emissions increased after fertilization in March and ploughing in late September. In GC (fertilized with P and K), there was no N2O peak after grass cutting. Both from manual and automatic chamber systems, “hot moments” of N2O emissions contributed ∼16–79 % of cumulative emissions. By predicting hot moments and scheduling frequent measurements, manual chambers captured most of the N2O dynamics. The results indicated that the hot moments of N2O emissions were better quantified by automatic chambers, while some of the hot moments, for instance, fertilization and ploughing in Trit were accurately captured with manual chambers. Soil nitrate and ammonium were positively associated with N2O emissions, whereas biomass N uptake was negatively associated. We conclude that perennial (GC) is a promising system for high biomass production with low environmental impact. Strategies such as growing spring barley as a catch crop, grass seeding with shallow tillage, and fertilization of newly seeded grass matching crop N demand are needed to reduce the higher risk for N losses.

AB - Perennials can produce more biomass and partially replace annual crops. However, environmental benefits of perennials over annuals in terms of nitrous oxide (N2O) emissions have rarely been compared in a long-term field experiment. By combining automatic and manual chamber methods, we aimed to develop reliable N2O estimates from annual and perennial systems. We measured N2O emissions from: i. perennial grass during renovation including spring barley as catch crop (SB/RG); ii. perennial grass-clover mixture (GC); iii. triticale monoculture (Trit). Results showed that cumulative N2O emissions from SB/RG were higher than GC or Trit. The highest emission rate was measured for SB/RG (258.9 µg N2O[sbnd]N m-2 h-1) after fertilization in spring. Increased N2O emissions were also seen for a short period after direct grass seeding in August. For Trit, N2O emissions increased after fertilization in March and ploughing in late September. In GC (fertilized with P and K), there was no N2O peak after grass cutting. Both from manual and automatic chamber systems, “hot moments” of N2O emissions contributed ∼16–79 % of cumulative emissions. By predicting hot moments and scheduling frequent measurements, manual chambers captured most of the N2O dynamics. The results indicated that the hot moments of N2O emissions were better quantified by automatic chambers, while some of the hot moments, for instance, fertilization and ploughing in Trit were accurately captured with manual chambers. Soil nitrate and ammonium were positively associated with N2O emissions, whereas biomass N uptake was negatively associated. We conclude that perennial (GC) is a promising system for high biomass production with low environmental impact. Strategies such as growing spring barley as a catch crop, grass seeding with shallow tillage, and fertilization of newly seeded grass matching crop N demand are needed to reduce the higher risk for N losses.

KW - Biomass n uptake

KW - Grass-clover

KW - Grassland renovation

KW - Long-term site

UR - http://www.scopus.com/inward/record.url?scp=105001490365&partnerID=8YFLogxK

U2 - 10.1016/j.agrformet.2025.110530

DO - 10.1016/j.agrformet.2025.110530

M3 - Journal article

AN - SCOPUS:105001490365

SN - 0168-1923

VL - 367

JO - Agricultural and Forest Meteorology

JF - Agricultural and Forest Meteorology

M1 - 110530

ER -

Combining automated and manual chambers to provide reliable estimates of N₂O emissions in annual and perennial cropping systems

Abstract

Keywords

Access to Document

Other files and links

Fingerprint

Cite this