AI Article Synopsis
- The study addresses the impact of plant functional type deficiencies on mixed litter humification in coniferous forests and alpine shrublands through a 1279-day decomposition experiment.
- Results revealed that humus concentrations and net accumulations were higher in coniferous forests than in alpine shrublands initially, but declined significantly over time, with different interactions between plant functional types affecting acid formation.
- Environmental factors, especially in the early stages, played a crucial role in litter humification, while specific chemical concentrations were identified as stimulants or inhibitors to humus accumulation, highlighting the importance of plant diversity for carbon sequestration in alpine ecosystems.
Article Abstract
Loss of plant diversity affects mountain ecosystem properties and processes, yet few studies have focused on the impact of plant function type deficiency on mixed litter humification. To fill this knowledge gap, we conducted a 1279-day litterbag decomposition experiment with six plant functional types of foliar litter to determine the temporal dynamic characteristics of mixed litter humification in a coniferous forest (CF) and an alpine shrubland (AS). The results indicated that the humus concentrations, the net accumulations and their relative mixed effects (RME) of most types were higher in CF than those in AS at 146 days, and humus net accumulations fell to approximately -80% of the initial level within 1279 days. The RME of the total humus and humic acid concentrations exhibited a general change from synergistic to antagonistic effects over time, but the mixing of single plant functional type impeded the formation of fulvic acid due to consistently exhibited antagonistic effects. Ultimately, correlation analysis indicated that environmental factors (temperature, snow depth and freeze-thaw cycles) significantly hindered litter humification in the early stage, while some initial quality factors drove this process at a longer scale. Among these aspects, the concentrations of zinc, copper and iron, as well as acid-unhydrolyzable residue (AUR):nitrogen and AUR:phosphorous, stimulated humus accumulation, while water-soluble extractables, potassium, magnesium and aluminium hampered it. Deficiencies in a single plant functional type and vegetation type variations affected litter humification at the alpine treeline, which will further affect soil carbon sequestration, which is of great significance for understanding the material circulation of alpine ecosystems.
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| http://dx.doi.org/10.1016/j.scitotenv.2021.150122 | DOI Listing |
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