Rates and intensity of freeze–thaw cycles affect nitrous oxide and carbon dioxide emissions from agricultural soils

In cool temperate regions, large emissions of nitrous oxide (N2O), an important greenhouse and ozone-depleting gas, have been observed during freeze–thaw (FT) cycles. However, it is unclear how freezing and thawing rates, freezing intensity, and freezing duration influence N2O emissions. We used a l...

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Bibliographic Details
Published in:Canadian Journal of Soil Science 2019-12, Vol.99 (4), p.472-484
Main Authors: Pelster, David E, Chantigny, Martin H, Rochette, Philippe, Bertrand, Normand, Angers, Denis A, Zebarth, Bernie J, Goyer, Claudia
Format: Article
Language:English
Subjects:
Agricultural land
Carbon dioxide
Carbon dioxide emissions
dégel
Emission measurements
Emissions
Fluxes
Freeze thaw cycles
Freeze-thawing
Freezing
Frozen ground
gel
Loam
Nitrous oxide
oxyde nitreux
Ozone
Ozone depletion
respiration du sol
Sandy loam
Sandy soils
soil respiration
Soil surfaces
Soils
Sol-gel processes
Temperature
Terrain
Thawing
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Summary:In cool temperate regions, large emissions of nitrous oxide (N2O), an important greenhouse and ozone-depleting gas, have been observed during freeze–thaw (FT) cycles. However, it is unclear how freezing and thawing rates, freezing intensity, and freezing duration influence N2O emissions. We used a laboratory incubation to measure N2O emissions from two soils (sandy loam, silty clay) undergoing a single FT cycle of various freezing and thawing rates [rapid (0.5 °C h-1) vs. slow (0.017 °C h-1)], freezing intensity (-1 vs. -3 °C), and freezing duration (24 vs. 48 freezing degree-days). In general, soil carbon dioxide fluxes during freezing were highest when soils were frozen slowly at -1 °C, whereas fluxes after thawing were highest from the soils frozen and thawed rapidly at -3 °C. Soil N2O emissions during both the freezing and thawing periods were greatest in the soils exposed to rapid freezing to -3 °C, intermediate under rapid freezing to -1 °C and slow freezing to -3 °C, and smallest under slow freezing to -1 °C and the control treatment (constant +1 °C). The similar N2O emissions between the unfrozen control and the slowly frozen -1 °C treatment was unexpected as previous field studies with similar freezing rates and temperatures still experienced high N2O emissions during thaw. This suggests that the physical disruptions caused by freezing and thawing of the surface soil are not the primary driver of FT-induced N2O emissions under field conditions.
ISSN:0008-4271
1918-1841
1918-1833
DOI:10.1139/cjss-2019-0058