Abstract
Progressively higher atmospheric nitrogen (N) deposition increasingly affects soil ecosystems' elemental cycling and stability. Biochar (BC) amendment has emerged as a possible means of preserving soil system stability. Nevertheless, the pattern of soil-microbial nutrient cycling and system stability in response to BC after high N deposition in ecologically sensitive regions remains uncertain. Therefore, we investigated the effects of high N (9 g N·m(-2)·a(-1)), BC (0, 20, 40 t·ha(-1)), and combinations of the treatments on soil organic carbon (SOC), total nitrogen (TN), total phosphorus (TP), microbial biomass carbon (MBC), nitrogen (MBN), phosphorus (MBP), microbial entropy (q (MB)), and stoichiometric imbalance (C(imb):N(imb):P(imb)). We found that high N addition decreased topsoil (0-20 cm) TP, C:N, q (MBN), and C(imb):N(imb) values and increased TN, C:P, N:P, q (MBP), C(imb):P(imb), and N(imb):P(imb) values. However, BC addition increased 0-40 cm soil q (MBC) and N(imb):P(imb) values and decreased q (MBN), C(imb):N(imb), and C(imb):P(imb) values. Meanwhile, high BC additions attenuated BC's promotion of soil-microbial nutrients. We observed that a mixture of high N and BC increased the 0-40 cm SOC and TP content, promoted the accumulation of MBN and MBP in the subsoil (20-40 cm), and decreased the topsoil C(imb):P(imb) and N(imb):P(imb) values compared to high N additions. The impact of high N and BC additions on N and P elements varied significantly between the different soil depths. In addition, redundancy analysis identified C:N, MBC, MBN, and C:P as pivotal factors affecting alterations in soil q (MB) and stoichiometric imbalance. Overall, adding BC reduced the negative impacts of high N deposition on the stability of soil-microbial systems in the Loess Plateau, suggesting a new approach for managing ecologically fragile areas.