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Irrigation with oxygen-nanobubble water can reduce methane emission and arsenic dissolution in a flooded rice paddy
A remarkable feature of nanobubbles (<10 ^–6 m in diameter) is their long lifetime in water. Supplying oxygen-nanobubbles (NBs) to continuously flooded paddy soil may retard the development of reductive conditions, thereby reducing the emission of methane (CH _4 ), a potent greenhouse gas, and dissolution of arsenic, an environmental load. We tested this hypothesis by performing a pot experiment and measuring redox-related variables. The NBs were introduced into control water (with properties similar to those of river water) using a commercially available generator. Rice ( Oryza sativa L.) growth did not differ between plants irrigated with NB water and those irrigated with control water, but NB water significantly ( p < 0.05) reduced cumulative CH _4 emission during the rice-growing season by 21%. The amounts of iron, manganese, and arsenic that leached into the drainage water before full rice heading were also reduced by the NB water. Regardless of the water type, weekly-measured CH _4 flux was linearly correlated with the leached iron concentration during the rice-growing season ( r = 0.74, p < 0.001). At the end of the experiment, the NB water significantly lowered the soil pH in the 0–5 cm layer, probably because of the raised redox potential. The population of methanogenic Archaea ( mcrA copy number) in the 0–5 cm layer was significantly increased by the NB water, but we found no correlation between the mcrA copy number and the cumulative CH _4 emission ( r = –0.08, p = 0.85). In pots without rice plants, soil reduction was not enhanced, regardless of the water type. The results indicate that NB water reduced CH _4 emission and arsenic dissolution through an oxidative shift of the redox conditions in the flooded soil. We propose the use of NB water as a tool for controlling redox conditions in flooded paddy soils.
Irrigation with oxygen-nanobubble water can reduce methane emission and arsenic dissolution in a flooded rice paddy
A remarkable feature of nanobubbles (<10 ^–6 m in diameter) is their long lifetime in water. Supplying oxygen-nanobubbles (NBs) to continuously flooded paddy soil may retard the development of reductive conditions, thereby reducing the emission of methane (CH _4 ), a potent greenhouse gas, and dissolution of arsenic, an environmental load. We tested this hypothesis by performing a pot experiment and measuring redox-related variables. The NBs were introduced into control water (with properties similar to those of river water) using a commercially available generator. Rice ( Oryza sativa L.) growth did not differ between plants irrigated with NB water and those irrigated with control water, but NB water significantly ( p < 0.05) reduced cumulative CH _4 emission during the rice-growing season by 21%. The amounts of iron, manganese, and arsenic that leached into the drainage water before full rice heading were also reduced by the NB water. Regardless of the water type, weekly-measured CH _4 flux was linearly correlated with the leached iron concentration during the rice-growing season ( r = 0.74, p < 0.001). At the end of the experiment, the NB water significantly lowered the soil pH in the 0–5 cm layer, probably because of the raised redox potential. The population of methanogenic Archaea ( mcrA copy number) in the 0–5 cm layer was significantly increased by the NB water, but we found no correlation between the mcrA copy number and the cumulative CH _4 emission ( r = –0.08, p = 0.85). In pots without rice plants, soil reduction was not enhanced, regardless of the water type. The results indicate that NB water reduced CH _4 emission and arsenic dissolution through an oxidative shift of the redox conditions in the flooded soil. We propose the use of NB water as a tool for controlling redox conditions in flooded paddy soils.
Irrigation with oxygen-nanobubble water can reduce methane emission and arsenic dissolution in a flooded rice paddy
Kazunori Minamikawa (author) / Masayoshi Takahashi (author) / Tomoyuki Makino (author) / Kanako Tago (author) / Masahito Hayatsu (author)
2015
Article (Journal)
Electronic Resource
Unknown
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