Abstract
Abstract. Forest fires modify soil organic carbon and suppress soil respiration for many decades after the initial disturbance. The associated changes in soil autotrophic and heterotrophic respiration from the time of the forest fire, however, are less well characterized. The FireResp model predicts soil autotrophic and heterotrophic respiration parameterized with a novel dataset across a fire chronosequence in the Yukon and Northwest Territories of Canada. The dataset consisted of soil incubation experiments and field measurements of soil respiration and soil carbon stocks. The FireResp model contains submodels that consider a Q10 (exponential) model of respiration compared to models of heterotrophic respiration using Michaelis–Menten kinetics parameterized with soil microbial carbon. For model evaluation we applied the Akaike information criterion and compared predicted patterns in components of soil respiration across the chronosequence. Parameters estimated with data from the 5 cm soil depth had better model–data comparisons than parameters estimated with data from the 10 cm soil depth. The model–data fit was improved by including parameters estimated from soil incubation experiments. Models that incorporated microbial carbon with Michaelis–Menten kinetics reproduced patterns in autotrophic and heterotrophic soil respiration components across the chronosequence. Autotrophic respiration was associated with aboveground tree biomass at more recently burned sites, but this association was less robust at older sites in the chronosequence. Our results provide support for more structured soil respiration models than standard Q10 exponential models.
Highlights
While containing 15 % of the total global soil area, highlatitude permafrost soils contain a significant proportion of global organic matter and global soil carbon content (Schuur et al, 2008; McGuire et al, 2009)
Heterotrophic respiration consists of microbial respiration of labile carbon and microbial respiration associated with the breakdown of dead organic matter and other by-products (Bosatta and Ågren, 2002; Harmon et al, 2011)
As these patterns conform to changes in root carbon, we have initial support for our two primary hypotheses: (1) autotrophic respiration should be positively associated with the time since disturbance because of changes in aboveground foliar vegetation from forest succession, and (2) when tested against observational data, soil models that include soil microbial carbon will better replicate expected patterns for soil respiration components across the chronosequence
Summary
While containing 15 % of the total global soil area, highlatitude permafrost soils contain a significant proportion of global organic matter and global soil carbon content (Schuur et al, 2008; McGuire et al, 2009) These high-latitude regions are warming faster than the rest of the world, consequentially leading to (1) drier soils during the spring and summer (Masrur et al, 2018), (2) increases in the intensity and frequency of forest fires (Walsh et al, 2020), and (3) destabilization of the permafrost extent (Schuur et al, 2008; McGuire et al, 2009).
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
