Dissimilatory Fe(Ⅲ) reduction is an important process in the geochemical cycle of iron in anoxic environment. As the main products of dissimilatory iron reduction, the Fe(Ⅱ) species accumulation could indicate t...Dissimilatory Fe(Ⅲ) reduction is an important process in the geochemical cycle of iron in anoxic environment. As the main products of dissimilatory iron reduction, the Fe(Ⅱ) species accumulation could indicate the reduction ability. The effects of different green manures on Fe(Ⅲ) reduction in paddy soil were explored based on a 31-year rice-rice-winter green manure cropping experiment. Four treatments were involved, i.e., rice-rice-milk vetch (RRV), rice-rice-rape (RRP), rice-rice-ryegrass (RRG) and rice-rice-winter fallow (RRF). Soils were sampled at flowering stage of milk vetch and rape (S1), before transplantation (S2), at tillering (S3), jointing (S4), and mature (S5) stages of the early rice, and after the harvest of the late rice (S6). The contents of TFeHa (HCI-extractable total Fe), Fe(Ⅱ)HCI (HCI-extractable Fe(Ⅱ) species) and Fe(Ⅲ)HCI (HCI- extractable Fe(Ⅲ) species) were measured. The correlations among those Fe species with selected soil environmental factors and the dynamic characteristics of Fe(Ⅱ)HCI accumulation were investigated. The results showed that TFeHc~ in RRF was significantly higher than those in the green manure treatments at most of the sampling stages. Fe(II)Ha increased rapidly after the incorporation of green manures in all treatments and kept rising with the growth of early rice. Fe(Ⅱ)Ha in RRG was quite different from those in other treatments, i.e., it reached the highest at the S2 stage, then increased slowly and became the lowest one at the S4 and S5 stages. Fe(Ⅲ)Ha showed oppositely, and Fe(Ⅱ)HCI/Fe(Ⅲ)HCI performed similarly to Fe(Ⅱ)HCI The maximum accumulation potential of Fe(Ⅱ)HCI was significantly higher in RRF, while the highest maximum reaction rate of Fe(Ⅱ)Ha accumulation appeared in RRG. Significant correlations were found between the indexes of Fe(Ⅱ)HCI accumulation and soil pH, oxidation-reduction potential (Eh) and total organic acids, respectively. In together, we found that long-term application of green manures decreased the TFeHa in red paddy soils, but promoted the ability of Fe(lll) reduction, especially the ryegrass; Fe(Ⅱ)Ha increased along with the growth of rice and was affected by soil conditions and environmental factors, especially the water and redox ability.展开更多
基金supported by the Special Fund for Agroscientific Research in the Public Interest,China(201103005)the Science and Technology Innovation Project of Chinese Academy of Agricultural Sciences(2013–2017)
文摘Dissimilatory Fe(Ⅲ) reduction is an important process in the geochemical cycle of iron in anoxic environment. As the main products of dissimilatory iron reduction, the Fe(Ⅱ) species accumulation could indicate the reduction ability. The effects of different green manures on Fe(Ⅲ) reduction in paddy soil were explored based on a 31-year rice-rice-winter green manure cropping experiment. Four treatments were involved, i.e., rice-rice-milk vetch (RRV), rice-rice-rape (RRP), rice-rice-ryegrass (RRG) and rice-rice-winter fallow (RRF). Soils were sampled at flowering stage of milk vetch and rape (S1), before transplantation (S2), at tillering (S3), jointing (S4), and mature (S5) stages of the early rice, and after the harvest of the late rice (S6). The contents of TFeHa (HCI-extractable total Fe), Fe(Ⅱ)HCI (HCI-extractable Fe(Ⅱ) species) and Fe(Ⅲ)HCI (HCI- extractable Fe(Ⅲ) species) were measured. The correlations among those Fe species with selected soil environmental factors and the dynamic characteristics of Fe(Ⅱ)HCI accumulation were investigated. The results showed that TFeHc~ in RRF was significantly higher than those in the green manure treatments at most of the sampling stages. Fe(II)Ha increased rapidly after the incorporation of green manures in all treatments and kept rising with the growth of early rice. Fe(Ⅱ)Ha in RRG was quite different from those in other treatments, i.e., it reached the highest at the S2 stage, then increased slowly and became the lowest one at the S4 and S5 stages. Fe(Ⅲ)Ha showed oppositely, and Fe(Ⅱ)HCI/Fe(Ⅲ)HCI performed similarly to Fe(Ⅱ)HCI The maximum accumulation potential of Fe(Ⅱ)HCI was significantly higher in RRF, while the highest maximum reaction rate of Fe(Ⅱ)Ha accumulation appeared in RRG. Significant correlations were found between the indexes of Fe(Ⅱ)HCI accumulation and soil pH, oxidation-reduction potential (Eh) and total organic acids, respectively. In together, we found that long-term application of green manures decreased the TFeHa in red paddy soils, but promoted the ability of Fe(lll) reduction, especially the ryegrass; Fe(Ⅱ)Ha increased along with the growth of rice and was affected by soil conditions and environmental factors, especially the water and redox ability.
