Effect of N and P fertilization on the allocation and fixation of photosynthesized carbon in paddy soil

• Main Authors: Mostafa Zhran, Tida Ge, Yaoyao Tong, Zhenke Zhu, Yangwu Deng, Ahmed Fahmy, Ming Chen, Tin Mar Lynn, Jinshui Wu, Anna Gunina
• Format: Article
• Language: English
• Published: Taylor & Francis Group 2021-01-01
• Series: Ecosystem Health and Sustainability
• Subjects: paddy soil; 13co2 continuous labeling; fertilization; carbon input; rhizosphere; bulk soil
• Online Access: http://dx.doi.org/10.1080/20964129.2021.1941271

Potted rice seedlings independently treated with N, P, and NP were continuously13CO2 labeled to investigated the influence of N and P application on the contribution of photosynthesized C to the rhizosphere versus bulk soil and particulate organic matter (POM) versus mineral fraction (MIN). N and NP enhanced net assimilated 13C on day 14 (D14), with maximum C assimilation occurring on day 22 (D22) under NP. Aboveground biomass retained more 13C than belowground biomass for all treatments. 13C incorporation into the rhizosphere exceeded that in bulk soil, with the maximum (6–10%) found under N addition. Newly assimilated 13C incorporated into POM increased in the rhizosphere under N and NP conditions, whereas MIN remained largely unaffected. 13C-MBC proportion in the total microbial biomass C (MBC) pool revealed that N and NP stimulated microbial activity to a greater degree than P. The main portion of 13C in the rhizosphere and bulk soil was found in POM on D14, which decreased over time due to microbial utilization. Contrastingly, root-derived 13C in the MIN remained unchanged between sampling days, which indicates that the stabilization of rhizodeposits in this fraction might be the potential mechanism underlying SOM sequestration in paddy soils.