Fire decreases soil respiration and its components in terrestrial ecosystems
Data files
Sep 20, 2023 version files 294.25 KB
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FEHESA1na.xlsx
290.77 KB
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README.md
3.48 KB
Abstract
- The impact of fire on aboveground biomass has significant consequences on soil carbon (C) dynamics, which is essential in predicting the global C budget during the Anthropocene. However, there is considerable spatiotemporal variability in the directions and magnitudes of fire effects on soil respiration, and the drivers associated with these effects are not well understood.
- Here, we conducted a global meta-analysis of 1327 individual observations from 170 studies to determine the extent to which fire influenced soil total respiration (Rs), heterotrophic respiration (Rh), and autotrophic respiration (Ra).
- We found fires reduced Rs, Rh, and Ra, with an average effect of -11.0%, -17.5%, and -40.6%, compared to unburnt sites. Specifically, wildfires significantly reduced Rsand Rh (-20.4% and -25.0%, respectively), and prescribed fire significantly decreased Ra (-74.8%). The influences of fire on Rs and its components were moderated by fire severity, season, type, climate zones, and biomes. After several years from the time of the fire, the negative effects of fire on Rs diminished and then recovered to a state not significantly different from unburnt sites; Rh exhibited a similar but decayed temporal response. Similarly, the negative effects on Ra disappeared after 3 years following the latest fire. The magnitude of the effect on Rs was strongly associated with soil temperature, cation exchange capacity, total nitrogen (N) content, and N-acquiring enzyme activity. In contrast, the magnitude of the effect on Rh significantly changed with pH, bulk density, texture, soil C and nutrient contents, and C- acquiring enzyme activity.
- Our findings advance the understanding of the inhibition and associated mechanisms of fire on Rs and its components, highlighting the need for new research efforts to predict the spatial-temporal shifts in underground C cycling induced by fire.
README: Fire decreases soil respiration and its components in terrestrial ecosystems
https://doi.org/10.5061/dryad.x3ffbg7r9
Description of the data and file structure
Our global dataset comprises a comprehensive compilation of measurements for soil respiration and its components (total respiration, heterotrophic respiration, and autotrophic respiration). The dataset also includes a large set of covariates, such as spatial coordinates (latitude and longitude), climate variables (mean annual temperature and mean annual precipitation), and soil abiotic and biotic properties (e.g., pH, temperature, moisture, C, N, and P contents, bulk density, cation exchange capacity, microbial biomass C and N, and enzyme activities).
Details of the Individual Variables:
- Reference: Source of the data
- Latitude: Latitude of the site (°); positive values represent northern latitudes, and negative values represent southern latitudes.
- Longitude: Longitude of the site (°); positive values represent eastern longitudes, and negative values represent western longitudes.
- MAT: Mean annual temperature (℃)
- MAP: Mean annual precipitation (mm)
- Biome: Biome of the site
- Forest type: Forest type of the site; "null" indicates the site is not a forest.
- Climate zone: Climate zone of the site
- Fire type: Type of fire
- Fire severity: Severity of the fire
- Fire season: Burning season of the last fire
- Post-fire Time: Time since the last fire (month)
- Respiration: Measured respiration components; Rs, Rh, and Ra represent total respiration, heterotrophic respiration, and autotrophic respiration, respectively.
- yi: Response ratio of respiration (unitless)
- vi: Variance of the response ratio of respiration (unitless)
- pH: Changes in soil pH (unitless)
- ST: Response ratio of soil temperature (unitless)
- Moisture: Response ratio of soil moisture (unitless)
- Clay: Response ratio of soil clay content (unitless)
- Silt: Response ratio of soil silt content (unitless)
- Sand: Response ratio of soil sand content (unitless)
- SOCck: Soil organic carbon content of unburnt observations (g/kg)
- SOC: Response ratio of soil organic carbon content (unitless)
- TC: Response ratio of soil total carbon content (unitless)
- TN: Response ratio of soil total nitrogen content (unitless)
- AP: Response ratio of available phosphorus content (unitless)
- CN: Response ratio of carbon-to-nitrogen ratio (unitless)
- BD: Response ratio of bulk density (unitless)
- CEC: Response ratio of cation exchange capacity (unitless)
- MBC: Response ratio of microbial biomass carbon content (unitless)
- MBN: Response ratio of microbial biomass nitrogen content (unitless)
- Ccyc: Response ratio of carbon-cycling enzyme activity (unitless)
- Ncyc: Response ratio of nitrogen-cycling enzyme activity (unitless)
- Pcyc: Response ratio of phosphorus-cycling enzyme activity (unitless)
- Ocyc: Response ratio of oxidase activity (unitless)
Missing values are indicated by "n/a".
Sharing/Access information
Code/Software
We extracted data directly from text, tables, figures, and appendices from the primary articles using the Getdata 2.2.5 software. In cases where site coordinates were not provided, we estimated them by referring to site descriptions and cited sources. Additionally, for unavailable climate data, we used a global database (http://www.worldclim.org/) and used spatial coordinates to fill in the missing climate data.
Methods
We extracted data directly from text, tables, figures, and appendices from the primary articles using the Getdata 2.2.5 software. In cases where site coordinates were not provided, we estimated them by referring to site descriptions and cited sources. Additionally, for unavailable climate data, we used a global database (http://www.worldclim.org/) and used spatial coordinates to fill in the missing climate data.