AI Article Synopsis
- Nitrogen was added to moss-dominated biological soil crusts (BSCs) and bare soil on the Chinese Loess Plateau to study N cycling.
- BSCs showed significantly higher levels of total nitrogen, microbial biomass nitrogen, and dissolved organic nitrogen compared to bare soil, indicating greater nitrogen retention and fixation capabilities.
- The study concluded that BSCs play a crucial role in nitrogen cycling by altering the distribution of nitrogen fractions and enhancing nitrogen storing capacity within dryland ecosystems.
Article Abstract
Nitrogen (N) labeled with N was evenly added into plots of moss-dominated biological soil crusts (BSCs) and bare soil on the Chinese Loess Plateau. After that, the surface BSCs and bare soil samples were continuously collected within 1-30 days. The N content of each N fraction in soil, microorganisms, and mosses was measured for each sample. The effects of BSCs on soil N fate and cycling was determined through analyzing the differences in the distribution of N fractions between the BSCs and bare soil. Our results showed that: 1) The N content of total N (TN), microbial biomass N (MBN), and dissolved organic N (DON) in the BSCs was 2.9, 17.5, and 9.0 times higher than that in the bare soil, respectively. The N content of moss plants in the BSCs was 4.73 mg kg. 2) The residual rate of N in the BSCs and bare soil was 13.0% and 3.3%, respectively, indicating that the N fixing and holding ability of BSCs was four times higher than that of bare soil. The percentage of each N fraction in TN in the BSCs was in the order of MBN (54.3%)>moss plant N (22.5%)>DON (6.2%), while that in the bare soil was in the order of MBN (11.5%)>DON (2.6%). Over all, microorganisms and mosses in the BSCs had 65.3% higher capacity of N fixation as compared with the bare soil. 3) The transferred amount and storage capacity of MBN in the BSCs were 17.2 and 20.5 times higher than that in the bare soil, respectively. Accordingly, the turnover rate of MBN in the BSCs and bare soil was 5.8 and 7.2 times per month, respectively, with the turnover time of MBN in the BSCs being 1.2 times longer than that in bare soil. In conclusion, BSCs fix and hold more N than bare soil and change the distribution of each N fraction, implying that BSCs play a critical role in N cycling in dryland ecosystems.
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| http://dx.doi.org/10.13287/j.1001-9332.202008.024 | DOI Listing |
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