Abstract
Carbon cycling research has increased over the past 20 years, but less is known about the primary contributors to soil respiration (i.e. heterotrophic and autotrophic) under dormant conditions. It is understood that soil CO2 effluxes are significantly lower during the winter of temperate ecosystems and assumed microorganisms dominate efflux origination. We hypothesized that heterotrophic contributions would be greater than autotrophic under simulated dormancy conditions. To test this hypothesis, we designed an experiment with the following treatments: combined autotrophic heterotrophic respiration, heterotrophic respiration, autotrophic respiration, no respiration, autotrophic respiration in vermiculite, and no respiration in vermiculite. Engelmann spruce seedlings and soil substrates were placed in specially designed respiration chambers and soil CO2 efflux measurements were taken four times over the course of a month. Soil microbial densities and root volumes were measured for each chamber after day thirty-three. Seedling presence resulted in significantly higher soil CO2 efflux rates for all soil substrates. Autotrophic respiration treatments were not representative of solely autotrophic soil CO2 efflux due to soil microbial contamination of autoclaved soil substrates; however, the mean autotrophic contributions averaged less than 25% of the total soil CO2 efflux. Soil microorganism communities were likely the primary contributor to soil CO2 efflux in simulated dormant conditions, as treatments with the greatest proportions of microbial densities had the highest soil CO2 efflux rates. Although this study is not directly comparable to field dormant season soil CO2 effluxes of Engelmann spruce forest, as snowpack is not maintained throughout this experiment, relationships, and metrics from such small-scale ecosystem component processes may yield more accurate carbon budget models.
Highlights
Soil CO2 efflux is the primary carbon efflux from terrestrial ecosystems to the atmosphere; soils and plant biomass represent the largest terrestrial carbon pools storing more than 1000 petagrams of carbon (Bradford, Birdsey, Joyce, & Ryan, 2008; Dixon et al, 1994; Raich & Schlesinger, 1992)
After accounting for covariables, treatments containing a seedling had significantly higher soil CO2 efflux rates than without a seedling for all three soil types, but the proportions of autotrophic contribution to the total soil CO2 efflux was less compared to the heterotrophic contribution in autoclaved soil (8.9%, p-value =
Our data suggest that fungal and bacterial soil communities are the major contributors to dormant season soil CO2 efflux, contributing approximately 75% of the total carbon efflux
Summary
Soil CO2 efflux is the primary carbon efflux from terrestrial ecosystems to the atmosphere; soils and plant biomass represent the largest terrestrial carbon pools storing more than 1000 petagrams (pg) of carbon (Bradford, Birdsey, Joyce, & Ryan, 2008; Dixon et al, 1994; Raich & Schlesinger, 1992). Soil CO2 efflux is composed of autotrophic (plant) and heterotrophic (microbial) metabolic processes, and is usually quantified at the soil surface as a single source flux (Amiro et al, 2010). Previous studies have attempted to separate autotrophic and heterotrophic fluxes, primarily utilizing three methods (i.e. root exclusion, component integration, and isotopic experiments) (Hanson, Edwards, Garten, & Andrews, 2000; Lee, Nakane, Nakatsubo, & Koizumi, 2003); many of these studies have limitations, as physically separating autotrophic and heterotrophic soil CO2 efflux contributions may influence available soil moisture and gas diffusion rates. Heterotrophic and autotrophic carbon efflux contributions to the gross soil carbon efflux are not well understood. We attempt to separate autotrophic and heterotrophic soil CO2 efflux under simulated dormant season conditions
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