Dataset associated with “Using isotope pool dilution to understand how organic carbon additions
affect N2O consumption in diverse soils”

Stuchiner, Emily R.; von Fischer, J. C.

Dataset associated with “Using isotope pool dilution to understand how organic carbon additions affect N2O consumption in diverse soils”

dc.contributor.author	Stuchiner, Emily R.
dc.contributor.author	von Fischer, J. C.
dc.coverage.spatial	Rocky Mountain National Park (Colo.)	en_US
dc.coverage.spatial	Fort Collins (Colo.)	en_US
dc.coverage.spatial	Nunn (Colo.)	en_US
dc.coverage.spatial	Greeley (Colo.)	en_US
dc.coverage.spatial	Socorro (N.M.)	en_US
dc.coverage.spatial	Ely (Minn.)	en_US
dc.coverage.spatial	Elrosa (Minn.)	en_US
dc.coverage.temporal	2019-06 – 2019-09	en_US
dc.date.accessioned	2022-03-30T22:22:23Z
dc.date.available	2022-03-30T22:22:23Z
dc.date.issued	2022
dc.description	This dataset includes information about eight soils collected from Colorado, New Mexico, and Minnesota. All soils were collected from June – July 2019. Five soils were collected in Colorado (two in Rocky Mountain National Park, one from a cornfield near Greeley, CO, one from a grassland near Nunn CO, and one from a lawn at Colorado State University). One soil was collected in New Mexico, from the Sevilleta National Grassland. Two soils were collected from Minnesota (one from a coniferous forest near Ely, MN, and one from a cornfield near Elrosa, MN). We subsampled these soils to analyze their soil chemical and microbial genetic properties, and we also subsampled these soils to analyze their nitrous oxide (N2O) emission and isotopic composition. The purpose of these analyses was to determine how amending soils with organic carbon influenced their capacity to produce and consume N2O. All of these analyses occurred at Colorado State University, from July – September 2019.	en_US
dc.description	Department of Biology
dc.description	Graduate Degree Program in Ecology
dc.description.abstract	Nitrous oxide (N2O) is a formidable greenhouse gas with warming potential ~300x greater than CO2. However, its emissions to the atmosphere have gone largely unchecked because the microbial and environmental controls governing N2O emissions have proven difficult to manage. The microbial process N2O consumption is the only know biotic pathway to remove N2O from soil pores and therefore reduce N2O emissions. Consequently, manipulating soils to increase N2O consumption by organic carbon (OC) additions has steadily gained interest. However, the response of N2O emissions to different OC additions are inconsistent, and it is unclear if lower N2O emissions are due to increased consumption, decreased production, or both. Simplified and systematic studies are needed to evaluate the efficacy of different OC additions on N2O consumption. We aimed to manipulate N2O consumption by amending soils with OC compounds (succinate, acetate, propionate) more directly available to denitrifiers. We hypothesized that N2O consumption is OC-limited and predicted these denitrifier-targeted additions would lead to enhanced N2O consumption and increased nosZ gene abundance. We incubated diverse soils in the laboratory and performed a 15N2O isotope pool dilution assay to disentangle microbial N2O emissions from consumption using laser-based spectroscopy. We found that amending soils with OC increased gross N2O consumption in six of eight soils tested. Furthermore, three of eight soils showed Increased N2O Consumption and Decreased N2O Emissions (ICDE), a phenomenon we introduce in this study as an N2O management ideal. All three ICDE soils had low soil OC content, suggesting ICDE is a response to relaxed C-limitation wherein C additions promote soil anoxia, consequently stimulating the reduction of N2O via denitrification. We suggest, generally, OC additions to low OC soils will reduce N2O emissions via ICDE. Future studies should prioritize methodical assessment of different, specific, OC-additions to determine which additions show ICDE in different soils.	en_US
dc.description.sponsorship	This research was funded by the Environmental Defense Fund, and the Graduate Degree Program in Ecology Small Research Grant.	en_US
dc.format.medium	CSV
dc.identifier.uri	https://hdl.handle.net/10217/234597
dc.identifier.uri	http://dx.doi.org/10.25675/10217/234597
dc.language	English	en_US
dc.language.iso	eng	en_US
dc.publisher	Colorado State University. Libraries	en_US
dc.relation.ispartof	Research Data
dc.relation.isreferencedby	Stuchiner, E. R., & von Fischer, J. C. (2022). Using isotope pool dilution to understand how organic carbon additions affect N2O consumption in diverse soils. Global Change Biology, 00, 1– 17. https://doi.org/10.1111/gcb.16190	en_US
dc.rights.license	The material is open access and distributed under the terms and conditions of the Creative Commons Public Domain "No rights reserved" (https://creativecommons.org/share-your-work/public-domain/cc0/).
dc.rights.uri	https://creativecommons.org/share-your-work/public-domain/cc0/
dc.subject	Soil N2O emission	en_US
dc.subject	Stimulate N2O consumption	en_US
dc.subject	Organic carbon amendments	en_US
dc.subject	Soil properties	en_US
dc.subject	nosZ gene abundance	en_US
dc.subject	15N isotope pool dilution	en_US
dc.subject	Microbial N-cycling genes	en_US
dc.title	Dataset associated with “Using isotope pool dilution to understand how organic carbon additions affect N2O consumption in diverse soils”	en_US
dc.type	Dataset	en_US