Effects of biochar amendment in two soils on greenhouse gas emissions and crop production
Background Worldwide, there is an increasing interest in using biochar in agriculture to help mitigate global warming and improve crop productivity. Methods The effects of biochar on greenhouse gas (GHG) emissions and rice and wheat yields were assessed using outdoor pot experiments in two different...
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| Published in | Plant and soil Vol. 360; no. 1-2; pp. 287 - 298 |
|---|---|
| Main Authors | , , , , |
| Format | Journal Article |
| Language | English |
| Published |
Dordrecht
Springer
01.11.2012
Springer Netherlands Springer Nature B.V |
| Subjects | |
| Online Access | Get full text |
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| Abstract | Background Worldwide, there is an increasing interest in using biochar in agriculture to help mitigate global warming and improve crop productivity. Methods The effects of biochar on greenhouse gas (GHG) emissions and rice and wheat yields were assessed using outdoor pot experiments in two different soils (upland soil vs. paddy soil) and an aerobic incubation experiment in the paddy soil. Results Biochar addition to the upland soil increased methane (CH4) emissions by 37 % during the rice season, while it had no effect on CH4 emissions during the wheat season. Biochar amendment decreased nitrous oxide (N2O) emissions up to 54 % and 53 % during the rice and wheat seasons, respectively, but had no effect on the ecosystem respiration in either crop season. In the aerobic incubation experiment, biochar addition significantly decreased N2O emissions and increased carbon dioxide (CO2) emissions from the paddy soil (P<0.01) without urea nitrogen. Biochar addition increased grain yield and biomass if applied with nitrogen fertilizer. Averaged over the two soils, biochar amendments increased the production of rice and wheat by 12 % and 17 %, respectively, and these increases can be partly attributed to the increases in soil nitrate retention. Conclusions Our results demonstrated that although biochar increased the global warming potential at high nitrogen fertilizer application, biochar incorporation significantly decreased N2O emissions while promoting crop production. |
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| AbstractList | Background
Worldwide, there is an increasing interest in using biochar in agriculture to help mitigate global warming and improve crop productivity.
Methods
The effects of biochar on greenhouse gas (GHG) emissions and rice and wheat yields were assessed using outdoor pot experiments in two different soils (upland soil vs. paddy soil) and an aerobic incubation experiment in the paddy soil.
Results
Biochar addition to the upland soil increased methane (CH
4
) emissions by 37 % during the rice season, while it had no effect on CH
4
emissions during the wheat season. Biochar amendment decreased nitrous oxide (N
2
O) emissions up to 54 % and 53 % during the rice and wheat seasons, respectively, but had no effect on the ecosystem respiration in either crop season. In the aerobic incubation experiment, biochar addition significantly decreased N
2
O emissions and increased carbon dioxide (CO
2
) emissions from the paddy soil (
P
< 0.01) without urea nitrogen. Biochar addition increased grain yield and biomass if applied with nitrogen fertilizer. Averaged over the two soils, biochar amendments increased the production of rice and wheat by 12 % and 17 %, respectively, and these increases can be partly attributed to the increases in soil nitrate retention.
Conclusions
Our results demonstrated that although biochar increased the global warming potential at high nitrogen fertilizer application, biochar incorporation significantly decreased N
2
O emissions while promoting crop production. Background Worldwide, there is an increasing interest in using biochar in agriculture to help mitigate global warming and improve crop productivity. Methods The effects of biochar on greenhouse gas (GHG) emissions and rice and wheat yields were assessed using outdoor pot experiments in two different soils (upland soil vs. paddy soil) and an aerobic incubation experiment in the paddy soil. Results Biochar addition to the upland soil increased methane (CH4) emissions by 37 % during the rice season, while it had no effect on CH4 emissions during the wheat season. Biochar amendment decreased nitrous oxide (N2O) emissions up to 54 % and 53 % during the rice and wheat seasons, respectively, but had no effect on the ecosystem respiration in either crop season. In the aerobic incubation experiment, biochar addition significantly decreased N2O emissions and increased carbon dioxide (CO2) emissions from the paddy soil (P<0.01) without urea nitrogen. Biochar addition increased grain yield and biomass if applied with nitrogen fertilizer. Averaged over the two soils, biochar amendments increased the production of rice and wheat by 12 % and 17 %, respectively, and these increases can be partly attributed to the increases in soil nitrate retention. Conclusions Our results demonstrated that although biochar increased the global warming potential at high nitrogen fertilizer application, biochar incorporation significantly decreased N2O emissions while promoting crop production. Background: Worldwide, there is an increasing interest in using biochar in agriculture to help mitigate global warming and improve crop productivity. Methods: The effects of biochar on greenhouse gas (GHG) emissions and rice and wheat yields were assessed using outdoor pot experiments in two different soils (upland soil vs. paddy soil) and an aerobic incubation experiment in the paddy soil. Results: Biochar addition to the upland soil increased methane (CH sub(4)) emissions by 37 % during the rice season, while it had no effect on CH sub(4) emissions during the wheat season. Biochar amendment decreased nitrous oxide (N sub(2)O) emissions up to 54 % and 53 % during the rice and wheat seasons, respectively, but had no effect on the ecosystem respiration in either crop season. In the aerobic incubation experiment, biochar addition significantly decreased N sub(2)O emissions and increased carbon dioxide (CO sub(2)) emissions from the paddy soil (P<0.01) without urea nitrogen. Biochar addition increased grain yield and biomass if applied with nitrogen fertilizer. Averaged over the two soils, biochar amendments increased the production of rice and wheat by 12 % and 17 %, respectively, and these increases can be partly attributed to the increases in soil nitrate retention. Conclusions: Our results demonstrated that although biochar increased the global warming potential at high nitrogen fertilizer application, biochar incorporation significantly decreased N sub(2)O emissions while promoting crop production. Background Worldwide, there is an increasing interest in using biochar in agriculture to help mitigate global warming and improve crop productivity. Methods The effects of biochar on greenhouse gas (GHG) emissions and rice and wheat yields were assessed using outdoor pot experiments in two different soils (upland soil vs. paddy soil) and an aerobic incubation experiment in the paddy soil. Results Biochar addition to the upland soil increased methane (C[H.sub.4]) emissions by 37 % during the rice season, while it had no effect on C[H.sub.4] emissions during the wheat season. Biochar amendment decreased nitrous oxide ([N.sub.2]O) emissions up to 54 % and 53 % during the rice and wheat seasons, respectively, but had no effect on the ecosystem respiration in either crop season. In the aerobic incubation experiment, biochar addition significantly decreased [N.sub.2]O emissions and increased carbon dioxide (C[O.sub.2]) emissions from the paddy soil (P<0.01) without urea nitrogen. Biochar addition increased grain yield and biomass if applied with nitrogen fertilizer. Averaged over the two soils, biochar amendments increased the production of rice and wheat by 12 % and 17 %, respectively, and these increases can be partly attributed to the increases in soil nitrate retention. Conclusions Our results demonstrated that although biochar increased the global warming potential at high nitrogen fertilizer application, biochar incorporation significantly decreased [N.sub.2]O emissions while promoting crop production. Keywords Biochar * Greenhouse gas emissions * Crop yield * Rice and wheat rotation * Paddy soil Worldwide, there is an increasing interest in using biochar in agriculture to help mitigate global warming and improve crop productivity. The effects of biochar on greenhouse gas (GHG) emissions and rice and wheat yields were assessed using outdoor pot experiments in two different soils (upland soil vs. paddy soil) and an aerobic incubation experiment in the paddy soil. Biochar addition to the upland soil increased methane (CH4) emissions by 37 % during the rice season, while it had no effect on CH4 emissions during the wheat season. Biochar amendment decreased nitrous oxide (N2O) emissions up to 54 % and 53 % during the rice and wheat seasons, respectively, but had no effect on the ecosystem respiration in either crop season. In the aerobic incubation experiment, biochar addition significantly decreased N2O emissions and increased carbon dioxide (CO2) emissions from the paddy soil (P<0.01) without urea nitrogen. Biochar addition increased grain yield and biomass if applied with nitrogen fertilizer. Averaged over the two soils, biochar amendments increased the production of rice and wheat by 12 % and 17 %, respectively, and these increases can be partly attributed to the increases in soil nitrate retention. Our results demonstrated that although biochar increased the global warming potential at high nitrogen fertilizer application, biochar incorporation significantly decreased N2O emissions while promoting crop production. [PUBLICATION ABSTRACT] |
| Audience | Academic |
| Author | Wang, Jinyang Pan, Xiaojian Liu, Yinglie Zhang, Xiaolin Xiong, Zhengqin |
| Author_xml | – sequence: 1 givenname: Jinyang surname: Wang fullname: Wang, Jinyang – sequence: 2 givenname: Xiaojian surname: Pan fullname: Pan, Xiaojian – sequence: 3 givenname: Yinglie surname: Liu fullname: Liu, Yinglie – sequence: 4 givenname: Xiaolin surname: Zhang fullname: Zhang, Xiaolin – sequence: 5 givenname: Zhengqin surname: Xiong fullname: Xiong, Zhengqin |
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| Copyright | Springer Science+Business Media B.V. 2012 2015 INIST-CNRS COPYRIGHT 2012 Springer Springer Science+Business Media Dordrecht 2012 |
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| DOI | 10.1007/s11104-012-1250-3 |
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| Keywords | Rice and wheat rotation Greenhouse gas emissions Biochar Crop yield Paddy soil Monocotyledones Gas emission Cultivated soil Carbonization Amendment Triticum Gramineae Greenhouse gas Angiospermae Paddy field Cultivated plant C3-Type Plant production Vegetals Cropping system Soil management Oryza Crop rotation Herbaceous plant Spermatophyta Yield Soil plant relation |
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| PublicationSubtitle | An International Journal on Plant-Soil Relationships |
| PublicationTitle | Plant and soil |
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| PublicationYear | 2012 |
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| Snippet | Background Worldwide, there is an increasing interest in using biochar in agriculture to help mitigate global warming and improve crop productivity. Methods... Background Worldwide, there is an increasing interest in using biochar in agriculture to help mitigate global warming and improve crop productivity. Methods... Worldwide, there is an increasing interest in using biochar in agriculture to help mitigate global warming and improve crop productivity. The effects of... Background: Worldwide, there is an increasing interest in using biochar in agriculture to help mitigate global warming and improve crop productivity. Methods:... BACKGROUND: Worldwide, there is an increasing interest in using biochar in agriculture to help mitigate global warming and improve crop productivity. METHODS:... |
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| SubjectTerms | Agricultural production Agricultural soils Agrology Agronomy. Soil science and plant productions Air pollution Animal, plant and microbial ecology Atmospheric carbon dioxide Biochar Biological and medical sciences Biomass Biomedical and Life Sciences Carbon dioxide Charcoal Climate change Crop production Crop rotation Ecology ecosystem respiration Emissions Farm buildings Fertilizer application Fundamental and applied biological sciences. Psychology General agronomy. Plant production Global warming Global warming potential grain yield greenhouse gas emissions Greenhouse gases greenhouse soils Harvesting Incubation Life Sciences Methane nitrates Nitrogen Nitrogen fertilizers Nitrous oxide Oryza sativa Other nutrients. Amendments. Solid and liquid wastes. Sludges and slurries Paddy soils Plant Physiology Plant Sciences Pollutant emissions Regular Article Rice Rice fields Rice soils Seasons Soil mechanics Soil science Soil Science & Conservation Soil-plant relationships. Soil fertility Soil-plant relationships. Soil fertility. Fertilization. Amendments Soils Triticum aestivum Upland soils Urea Urea as fertilizer urea nitrogen Wheat Wheat soils |
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| Title | Effects of biochar amendment in two soils on greenhouse gas emissions and crop production |
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