Data from: Wildfire strengthens the relationship between soil biodiversity and ecosystem multifunctionality in subtropical forests
Data files
Mar 09, 2026 version files 23.83 KB
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Data_upload.csv
21.75 KB
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README.md
2.08 KB
Abstract
Wildfires are disrupting and regenerating forces in nature that affect all ecosystem components. However, the impact of wildfires on soil multitrophic biodiversity and the resulting consequences for ecosystem multifunctionality (EMF) remain poorly understood. In this study, we sampled fire chronosequences (1-, 5-, 9-, and 27-year) from burned and unburned plots in subtropical Pinus yunnanensis forests to determine the soil biodiversity of a wide range of taxonomic groups (bacteria, fungi, protists, and nematodes), together with an extensive array of 38 ecosystem functions related to microbial activity, organic matter decomposition and mineralization, and nutrient cycling. The responses of soil biodiversity and EMF varied with soil depth and time since fire. In the surface layer (0–10 cm), a general pattern emerged in all taxonomic groups, with initial declines in soil biodiversity compared with the unburned plots, but the greatest losses occurred only at 5 years post-fire and reversed to positive in the long term. Ecosystem multifunctionality broadly followed this pattern, but the loss of EMF occurred earlier and lasted longer, indicating a lower resistance of EMF than of its supporting biodiversity. Biodiversity responses in the subsurface layer were generally weaker after an initial strong transient enhancement at 1 year. Notably, we found that regardless of the taxonomic group, fire systematically strengthened the relationship between soil biodiversity and EMF, thus promoting post-fire regeneration of EMF. This study sheds new light on the importance of biodiversity in the functioning of ecosystems in an era in which wildfire regimes are altered by global climate change.
Dataset DOI: 10.5061/dryad.sn02v6xd8
Description of the data and file structure
The dataset was generated from a field experiment conducted in subtropical forest ecosystems affected by wildfires. Soil and plant litter samples were collected along a fire chronosequence spanning 1, 5, 9, and 27 years since fire occurrence, including both burned and adjacent unburned control plots. A range of soil biotic (e.g., bacterial, fungal, protist, and nematode diversity) and abiotic (e.g., nutrient content, enzyme activity) indicators were measured to assess the impact of wildfire on soil biodiversity and ecosystem multifunctionality. Data were collected to support analyses of post-fire soil recovery, biodiversity-function relationships, and the temporal dynamics of ecosystem processes following wildfire disturbance.
Files and variables
File: Data_upload.csv
Description: Variables are expressed as response ratios.
Variables
- Treatment
- Time since fire (year)
- Bacterial richness
- Fungal richness
- Nematode richness
- Protist richness
- Soil DNA
- WHC: water holding capacity
- AP: available phosphorus
- DOC: dissolved organic carbon
- MBC: microbial biomass carbon
- SMR: Microbial respiration
- Litter mass
- NO3-N: nitrate
- NH4-N: ammonium
- N mineralization
- BRC: bacterial residual carbon
- FRC: fungal residual carbon
- TRC: total residual carbon
- BG: β-1,4-glucosidase
- BX: β-1,4-xylosidase
- CBH: cellobiohydrolase
- NAG: β-N-acetylglucosaminidase
- LAP: leucyl aminopeptidase
- ACP: acid phosphatase
- POX: phenol oxidase
- PER: total phosphorus
- Enzyme C:N
- Enzyme C:P
- Enzyme N:P
- Soil C:N
- Soil C:P
- Soil N:P
- Litter C:N
- Litter C:P
- Litter N:P
- TPs: total phosphorus storage
- TNs: total nitrogen storage
- SOCs: soil organic carbon storage
- Litter C
- Litter N
- Litter P
- Nematode biomass
- Woody biomass: