Methane and nitrous oxide emission characteristics of high-yielding rice field

As representative varieties of the four phases of the super rice breeding project in China, Lianyoupei 9 (LYP9), Y Liangyou 1 (YLY1), Y Liangyou 2 (YLY2), and Y Liangyou 900 (YLY900) achieved higher yield under optimal cultivation techniques. However, the impact of these high-yield rice varieties on...

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Veröffentlicht in:Environmental science and pollution research international 2021-03, Vol.28 (12), p.15021-15031
Hauptverfasser: Wang, Zi-Hao, Wang, Liu-Hang, Liang, He, Peng, Ting, Xia, Gui-Ping, Zhang, Jing, Zhao, Quan-Zhi
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container_title Environmental science and pollution research international
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creator Wang, Zi-Hao
Wang, Liu-Hang
Liang, He
Peng, Ting
Xia, Gui-Ping
Zhang, Jing
Zhao, Quan-Zhi
description As representative varieties of the four phases of the super rice breeding project in China, Lianyoupei 9 (LYP9), Y Liangyou 1 (YLY1), Y Liangyou 2 (YLY2), and Y Liangyou 900 (YLY900) achieved higher yield under optimal cultivation techniques. However, the impact of these high-yield rice varieties on greenhouse gas (GHG) emissions under high-yield cultivation management practices remains poorly understood. In this study, we conducted field experiments to investigate CH 4 and N 2 O emissions from paddies containing four elite rice varieties, managed with field drying at the ineffective tillering stage and alternate wet/dry irrigation at the grain-filling stage. The plants were fertilised with nitrogen (N) at three different rates. The results showed that CH 4 emission was highest at the tillering stage. N 2 O emission flux was dramatically increased by field drying at the ineffective tillering stage, and with the rate of N application. Rice variety was among the most important factors affecting CH 4 emission and global warming potential (GWP). N 2 O emission was mainly related to N application rate rather than rice variety. YLY2 achieved higher yield than LYP9, YLY1, and YLY900, and lower GHG emission than YLY900. Our results indicate that rice variety should be considered as a key factor to reduce GHG emissions from rice paddies under high-yield cultivation practices. Based on its high yield and low GHG emission at the study site, YLY2 may be an optimal rice variety.
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However, the impact of these high-yield rice varieties on greenhouse gas (GHG) emissions under high-yield cultivation management practices remains poorly understood. In this study, we conducted field experiments to investigate CH 4 and N 2 O emissions from paddies containing four elite rice varieties, managed with field drying at the ineffective tillering stage and alternate wet/dry irrigation at the grain-filling stage. The plants were fertilised with nitrogen (N) at three different rates. The results showed that CH 4 emission was highest at the tillering stage. N 2 O emission flux was dramatically increased by field drying at the ineffective tillering stage, and with the rate of N application. Rice variety was among the most important factors affecting CH 4 emission and global warming potential (GWP). N 2 O emission was mainly related to N application rate rather than rice variety. YLY2 achieved higher yield than LYP9, YLY1, and YLY900, and lower GHG emission than YLY900. Our results indicate that rice variety should be considered as a key factor to reduce GHG emissions from rice paddies under high-yield cultivation practices. 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However, the impact of these high-yield rice varieties on greenhouse gas (GHG) emissions under high-yield cultivation management practices remains poorly understood. In this study, we conducted field experiments to investigate CH 4 and N 2 O emissions from paddies containing four elite rice varieties, managed with field drying at the ineffective tillering stage and alternate wet/dry irrigation at the grain-filling stage. The plants were fertilised with nitrogen (N) at three different rates. The results showed that CH 4 emission was highest at the tillering stage. N 2 O emission flux was dramatically increased by field drying at the ineffective tillering stage, and with the rate of N application. Rice variety was among the most important factors affecting CH 4 emission and global warming potential (GWP). N 2 O emission was mainly related to N application rate rather than rice variety. YLY2 achieved higher yield than LYP9, YLY1, and YLY900, and lower GHG emission than YLY900. Our results indicate that rice variety should be considered as a key factor to reduce GHG emissions from rice paddies under high-yield cultivation practices. 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However, the impact of these high-yield rice varieties on greenhouse gas (GHG) emissions under high-yield cultivation management practices remains poorly understood. In this study, we conducted field experiments to investigate CH 4 and N 2 O emissions from paddies containing four elite rice varieties, managed with field drying at the ineffective tillering stage and alternate wet/dry irrigation at the grain-filling stage. The plants were fertilised with nitrogen (N) at three different rates. The results showed that CH 4 emission was highest at the tillering stage. N 2 O emission flux was dramatically increased by field drying at the ineffective tillering stage, and with the rate of N application. Rice variety was among the most important factors affecting CH 4 emission and global warming potential (GWP). N 2 O emission was mainly related to N application rate rather than rice variety. YLY2 achieved higher yield than LYP9, YLY1, and YLY900, and lower GHG emission than YLY900. Our results indicate that rice variety should be considered as a key factor to reduce GHG emissions from rice paddies under high-yield cultivation practices. Based on its high yield and low GHG emission at the study site, YLY2 may be an optimal rice variety.</abstract><cop>Berlin/Heidelberg</cop><pub>Springer Berlin Heidelberg</pub><pmid>33221993</pmid><doi>10.1007/s11356-020-11641-y</doi><tpages>11</tpages></addata></record>
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subjects Agricultural production
Agriculture
Aquatic Pollution
Atmospheric Protection/Air Quality Control/Air Pollution
China
Climate change
Cultivation
Cultivation techniques
Drying
Earth and Environmental Science
Ecotoxicology
Emission analysis
Emissions control
Environment
Environmental Chemistry
Environmental Health
Environmental science
Field tests
Floods
Global Warming
Greenhouse effect
Greenhouse gases
Irrigation
Methane
Methane - analysis
Nitrogen
Nitrous oxide
Nitrous Oxide - analysis
Oryza
Plant Breeding
Research Article
Rice
Rice fields
Soil
Waste Water Technology
Water Management
Water Pollution Control
title Methane and nitrous oxide emission characteristics of high-yielding rice field
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