4.1 Article

Legacy effect of elevated CO2 and N fertilization on mineralization and retention of rice (Oryza sativa L.) rhizodeposit-C in paddy soil aggregates

期刊

SOIL ECOLOGY LETTERS
卷 4, 期 1, 页码 78-91

出版社

SPRINGERNATURE
DOI: 10.1007/s42832-020-0066-y

关键词

Rice rhizodeposits; Isotope labeling; Aggregates; Elevated carbon dioxide; Nitrogen fertilizer

资金

  1. National Key Research and Development Program of China [2017YF-D0301504]
  2. National Natural Science Foundation of China [41671292, 41771334, 41877104, 42007097]
  3. NSFC [41811540031]
  4. JSPS [41811540031]
  5. Hunan Province Base for Scientific and Technological Innovation Cooperation [2018WK4012]
  6. Innovation Group of Natural Science Foundation of Hunan Province [2019JJ10003]
  7. Natural Science Foundation of Hunan Province for Excellent Young Scholars [2019JJ30028]
  8. Youth Innovation Team Project of ISA, CAS [2017QN-CXTD_GTD]

向作者/读者索取更多资源

Elevated CO2 and N fertilization during the rice growing season have a legacy effect on the subsequent mineralization and retention of rhizodeposits in paddy soils after harvest, with varying effects among different soil aggregates.
Rhizodeposits in rice paddy soil are important in global C sequestration and cycling. This study explored the effects of elevated CO2 and N fertilization during the rice growing season on the subsequent mineralization and retention of rhizodeposit-C in soil aggregates after harvest. Rice (Oryza saliva L.) was labeled with (CO2)-C-13 under ambient (400 ppm) and elevated (800 ppm) CO2 concentrations with and without N fertilization. After harvest, soil with labeled rhizodeposits was collected, separated into three aggregate size fractions, and flood-incubated for 100 d. The initial rhizodeposit-C-13 content of N-fertilized microaggregates was less than 65% of that of non-fertilized microaggregates. During the incubation of microaggregates separated from N-fertilized soils, 3%-9% and 9%-16% more proportion of rhizodeposit-C-1(3) was mineralized to (CO2)-C-13, and incorporated into the microbial biomass, respectively, while less was allocated to soil organic carbon than in the non-fertilized soils. Elevated CO2 increased the rhizodeposit-C-1(3) content of all aggregate fractions by 10%-80%, while it reduced cumulative (CO2)-C-13 emission and the bioavailable C pool size of rhizodeposit-C, especially in N-fertilized soil, except for the silt-clay fraction. It also resulted in up to 23% less rhizodeposit-C incorporated into the microbial biomass of the three soil aggregates, and up to 23% more incorporated into soil organic carbon. These results were relatively weak in the silt-clay fraction. Elevated CO2 and N fertilizer applied in rice growing season had a legacy effect on subsequent mineralization and retention of rhizodeposits in paddy soils after harvest, the extent of which varied among the soil aggregates. (C) Higher Education Press 2020

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