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Số người truy cập: 107,047,663
Azolla cover significantly decreased CH
4
but not N
2
O emissions from flooding rice paddy to atmosphere. Journal of Soil Science & Plant Nutrition.
Tác giả hoặc Nhóm tác giả:
Samuel Munyaka Kimani, Weiguo Cheng, Takamori Kanno, Toan Nguyen-Sy, Ryoko Abe, Aung Zaw Oo, Keitaro Tawaraya, and Shigeto Sudo
Nơi đăng:
Journal of Soil science and plant nutrition (SCIE, Q1).;
S
ố:
64;
Từ->đến trang
: 68-76;
Năm:
2017
Lĩnh vực:
Nông lâm ngư;
Loại:
Bài báo khoa học;
Thể loại:
Quốc tế
TÓM TẮT
Azolla (
Azolla filiculoides
) is a common aquatic fern that has been used successfully as a dual crop with lowland rice. It grows rapidly and has the ability to fix N2 for rice paddy. However, its ecological significance especially on greenhouse gases emissions remains unclear. To investigate the effect of azolla cover on methane (CH4) and nitrous oxide (N2O) emissions from rice paddy, a pot experiment with two treatments, control (rice plant only) and azolla cover (rice plus azolla covering on the flooding water), was carried out in Tsuruoka, Yamagata, Japan, in 2016. The results showed that the rice growth parameters, like shoot height, maximum and productive tiller numbers, and plant biomass were not significantly different between the two treatments. Dual cropping of azolla with rice significantly suppressed CH4 emissions, likely due to an increase in dissolved oxygen concentration and redox potential at the soil-water interface between flooding water and soil surface. There were significant (
P <
0.05) positive correlations between CH4 flux and night respiration (CO2 emissions) between the two treatments. The cumulated CH4 emissions during the growth period until 106 days after transplanting (DAT) was significantly lower at 36.2 g C m−2 from azolla cover treatment than that from control treatment pot at 55.4 g C m−2. A prolonged nonsignificant N2O emission under the azolla cover treatment after the initial highest peak at 15 DAT was recorded due to denitrification of the nitrate in initial soil. No further N2O emissions were recorded thereafter from both treatments. Azolla cover did not affect N2O emissions from both treatments.
ABSTRACT
Azolla (
Azolla filiculoides
) is a common aquatic fern that has been used successfully as a dual crop with lowland rice. It grows rapidly and has the ability to fix N2 for rice paddy. However, its ecological significance especially on greenhouse gases emissions remains unclear. To investigate the effect of azolla cover on methane (CH4) and nitrous oxide (N2O) emissions from rice paddy, a pot experiment with two treatments, control (rice plant only) and azolla cover (rice plus azolla covering on the flooding water), was carried out in Tsuruoka, Yamagata, Japan, in 2016. The results showed that the rice growth parameters, like shoot height, maximum and productive tiller numbers, and plant biomass were not significantly different between the two treatments. Dual cropping of azolla with rice significantly suppressed CH4 emissions, likely due to an increase in dissolved oxygen concentration and redox potential at the soil-water interface between flooding water and soil surface. There were significant (
P <
0.05) positive correlations between CH4 flux and night respiration (CO2 emissions) between the two treatments. The cumulated CH4 emissions during the growth period until 106 days after transplanting (DAT) was significantly lower at 36.2 g C m−2 from azolla cover treatment than that from control treatment pot at 55.4 g C m−2. A prolonged nonsignificant N2O emission under the azolla cover treatment after the initial highest peak at 15 DAT was recorded due to denitrification of the nitrate in initial soil. No further N2O emissions were recorded thereafter from both treatments. Azolla cover did not affect N2O emissions from both treatments.
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