Effects of sterilization techniques on chemodenitrification and N2O production in tropical peat soil microcosms

Chemodenitrification – the non-enzymatic process of nitrite reduction – may be an important sink for fixed nitrogen in tropical peatlands. Rates and products of chemodenitrification are dependent on O2, pH, Fe2+ concentration, and organic matter composition, which are variable across peat soils. Ass...

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Bibliographic Details
Published in:Biogeosciences 2019-12, Vol.16 (23), p.4601-4612
Main Authors: Buessecker, Steffen, Tylor, Kaitlyn, Nye, Joshua, Holbert, Keith E, Urquiza Muñoz, Jose D, Glass, Jennifer B, Hartnett, Hilairy E, Cadillo-Quiroz, Hinsby
Format: Article
Language:English
Subjects:
Abiotic factors
Autoclaving
Cell viability
Chloroform
Composition
Denitrification
Depletion
Iron
Irradiation
Mercury
Microcosms
Nitrites
Nitrous oxide
Organic chemistry
Organic matter
Organic soils
Peat
Peat soils
Peatlands
pH effects
Radiation
Soil
Soil treatment
Speciation
Sterilization
Test procedures
Tropical climate
Zinc
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Summary:Chemodenitrification – the non-enzymatic process of nitrite reduction – may be an important sink for fixed nitrogen in tropical peatlands. Rates and products of chemodenitrification are dependent on O2, pH, Fe2+ concentration, and organic matter composition, which are variable across peat soils. Assessing abiotic reaction pathways is difficult because sterilization and inhibition agents can alter the availability of reactants by changing iron speciation and organic matter composition. We compared six commonly used soil sterilization techniques – γ irradiation, chloroform, autoclaving, and the use of three different chemical inhibitors (mercury, zinc, and azide) – for their compatibility with chemodenitrification assays for tropical peatland soils (organic-rich, low-pH soil from the eastern Amazon). Out of the six techniques, γ irradiation resulted in soil treatments with the lowest cell viability and denitrification activity and the least effect on pH, iron speciation, and organic matter composition. Nitrite depletion rates in γ-irradiated soils were highly similar to untreated (live) soils, whereas other sterilization techniques showed deviations. Chemodenitrification was a dominant process of nitrite consumption in tropical peatland soils assayed in this study. Nitrous oxide (N2O) is one possible product of chemodenitrification reactions. Abiotic N2O production was low to moderate (3 %–16 % of converted nitrite), and different sterilization techniques lead to significant variations on production rates due to inherent processes or potential artifacts. Our work represents the first methodological basis for testing the abiotic denitrification and N2O production potential in tropical peatland soil.
ISSN:1726-4170
1726-4189
DOI:10.5194/bg-16-4601-2019