Effect of Maize Straw–Derived Biochar on Calcareous Arable Soil Organic Carbon Mineralization Under the Condition of with or Without Nitrogen-Fertilizer Addition

The object of this study was to explore the effect of biochar on Loess Plateau calcareous arable soil organic carbon mineralization under the condition of with or without nitrogen-fertilizer addition. Maize straw–derived biochars were prepared at 400 and 800 °C (BC400 and BC800), respectively. After...

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Bibliographic Details
Published in:Journal of soil science and plant nutrition 2020-12, Vol.20 (4), p.2606-2616
Main Authors: Wang, Chaoxu, Chang, Zhilin, Niu, Shujuan
Format: Article
Language:English
Subjects:
Agriculture
Arable land
Biomedical and Life Sciences
Calcareous soils
Carbon
Carbon content
Carbon dioxide
Carbon dioxide emissions
Carbonyl compounds
Carbonyls
Charcoal
Climate change
Corn
Corn straw
Dissolved organic carbon
Ecology
Environment
Experiments
Fertilizers
Functional groups
Greenhouse gases
Life Sciences
Mineralization
Nitrogen
Organic soils
Original Paper
Oxygen
Physicochemical properties
Plant Sciences
Plastics
Pore size
Pyrolysis
Soil amendment
Soil Science & Conservation
Soils
Straw
Temperature
Total organic carbon
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Summary:The object of this study was to explore the effect of biochar on Loess Plateau calcareous arable soil organic carbon mineralization under the condition of with or without nitrogen-fertilizer addition. Maize straw–derived biochars were prepared at 400 and 800 °C (BC400 and BC800), respectively. After physicochemical property determination, biochars were thoroughly mixed with soil at the mass ratio of 1% and 2% respectively, and a control without biochar addition was also arranged. Each treatment was carried out with 6 replicates, half of which were subjected to nitrogen-fertilizer addition. After 1-week preincubation, 50-day indoor static soil incubation experiment was carried out consecutively. Results showed that compared with BC400, pH, carbon content, alkaline oxygen-containing functional group, and specific surface area of BC800 significantly increased, while dissolved organic carbon, nitrogen, hydrogen, oxygen contents, carboxyl, carbonyl, and acidic oxygen-containing functional group significantly decreased. In the treatments without nitrogen-fertilizer addition, maize straw–derived biochar inhibited CO 2 emission, especially for BC800-1% and BC800-2%. However, in the treatments with nitrogen-fertilizer addition, the biochar promoted CO 2 emission, especially for BC400-1% and BC400-2%. Moreover, the pyrolysis temperature of biochar preparation showed more crucial impact on CO 2 emission than its application rate. CO 2 emission was significantly correlated with total organic carbon/inorganic nitrogen (TOC/IN) and dissolved organic carbon/inorganic nitrogen (DOC/IN). However, DOC/IN explained the variance of CO 2 emission with a higher degree than TOC/IN. Carbon/nitrogen mass ratio was the key factor in controlling CO 2 emission from biochar-amended soil, and DOC/IN showed more significant effect on CO 2 emission than TOC/IN.
ISSN:0718-9508
0718-9516
DOI:10.1007/s42729-020-00326-7