The influence of root decomposition on N2O fluxes and N2O microbial production pathways in soil with contrasting pore characteristics
- 1Department of Integrative Biology, Michigan State University, East Lansing, MI 48824, USA
- 2Department of Plant, Soil, and Microbial Sciences, Michigan State University, East Lansing, MI 48824, USA
- 3DOE Great Lakes Bioenergy Research Center, East Lansing, MI 48824, USA
An understanding of the drivers of hotspot/hot moments of N2O production is required to better constrain the global N2O budget and to plan the mitigation strategies. Hot spots are areas with very high N2O emission rates relative to the surrounding area, while hot moments are short periods of time with very high emission rates. As the decomposition of fresh organic matter is transitory in nature, it may have a strong influence on hotspot and hot moment N2O production. Roots are well known to be hotspots for microbial activity but roots direct contribution to N2O production and emissions in soil remain poorly understood.
In this study, we evaluated the role of root decomposition on N2O production and emissions, as a function of soil pore size and water content. We hypothesized that (i) the greatest N2O emissions will be observed from root decomposition in the soil dominated by large (>30 µm Ø) pores due to their high connectivity and (ii) enhanced N2O production by denitrification will be observed due to local anaerobic conditions, generated by O2 consumption by decomposers.
To evaluate the role of root decomposition on N2O production we used soil microcosms cultivated with switchgrass (Panicum virgatum L. variety Cave-in-rock). From the same composite soil samples we created two soil materials with contrasting pore architectures, namely soil with prevalence of large pores (≥ 35 μm Ø) and small pores (≤ 10 μm Ø). After four months of growing in a greenhouse, plants were cut and soil microcosms with roots were incubated in the dark at room T for 21 days, at two contrasting soil moisture conditions: 40% and 70% water filled pore space (WFPS). Gas headspace samples were collected at different time points during incubation for N2O and CO2 concentration analysis and isotopic characterization of N2O (δ15Nbulk, site preference (SP), and δ18O).
The daily emissions of N2O and CO2 from soil microcosms with grown roots showed the same trend during the incubation period and were significantly higher compared to soil microcosms without roots (control) (p < 0.05). Microcosm with large pores soil had significantly higher N2O flux rates compared to the microcosms with small pore soil for both soil moisture treatments (p < 0.001). The relationship between SP and δ18O (isotope mapping) indicated that heterotrophic bacterial denitrification strongly dominated N2O production between day 1 to 7 of the incubation (≥ 97%) and N2O reduction was higher during this period (40 – 60%) in soil microcosms with both pore size and moisture treatment. Later on, N2O reduction decreased (1 – 35%) while the share of nitrification/fungal sources increased for soil microcosms with large pores.
Our results indicated that decomposing roots acted as hotspots enhancing N2O emissions and N2O hotspots occurring during root decomposition are strongly influenced by soil pore architecture. While differences in soil pore architecture did not cause differences in N2O production process at the initial phase of decomposition, it might influence the relative contribution of N2O microbial production pathways in later stage of decomposition.
How to cite: Gil, J., Kim, K., Gandhi, H., Oerther, M., Ostrom, N., and Kravchenko, A.: The influence of root decomposition on N2O fluxes and N2O microbial production pathways in soil with contrasting pore characteristics, EGU General Assembly 2021, online, 19–30 Apr 2021, EGU21-13818, https://doi.org/10.5194/egusphere-egu21-13818, 2021.
Corresponding displays formerly uploaded have been withdrawn.