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Details of Award

NERC Reference : NE/V000624/1

Diurnal Variation in Soil Nitrous oxide Emissions (DIVINE): drivers and mechanisms

Grant Award

Principal Investigator:
Professor JWB Moir, University of York, Environment
Science Area:
Atmospheric
Terrestrial
Overall Classification:
Panel C
ENRIs:
Global Change
Natural Resource Management
Science Topics:
Carbon allocation
Carbon/nitrogen assimilation
Circadian rhythm (plants)
Photosynthesis in plants
Plant physiology
Respiration (plants)
Roots
Shoots
Transport processes
Plant physiology
Biogeochemical Cycles
Carbon cycling
Microbial communities
Nitrogen cycling
Primary production
Soil biochemistry
Soil organics
Ecosystem Scale Processes
Agriculture
Biogeochemical cycles
Dissolved organic material
Ecosystem function
Ecosystem management
Ecosystem services
Food security
Greenhouse gas emission
Land surface modelling
Soil carbon
Terrestrial ecosystems
Land - Atmosphere Interactions
Carbon fluxes
Element cycles
Greenhouse gases
Microbial communities
Nitrification denitirifcation
Nutrient cycling
Vegetation management
Soil science
Ammonia oxidising bacteria
Land use
Microbial communities
Nutrient cycling
Plant-soil interactions
Rhizosphere biology
Soil biology
Soil compaction
Soil ecosystems
Soil management
Soil microbiology
Soil organics
Soil process modelling
Soil science
Soil structure
Abstract:
Nitrous oxide (N2O) is a potent greenhouse gas (GHG) with a global warming potential 298 times that of carbon dioxide. Agriculture contributes approximately two thirds of anthropogenic N2O emissions and is the most challenging sector for emissions reductions. Agriculture is also the largest source of uncertainty for national GHG reporting because N2O emissions are highly variable in space and time and consequently difficult to measure accurately. To achieve the enormous reductions urgently needed, we must be able to accurately measure and predict soil N2O emissions. Our work has demonstrated that N2O emissions can vary diurnally by up to 400% in agricultural soils. This diurnal variation is not captured in current measurements and predictions of N2O emissions. In DIVINE we will investigate for the first time, the mechanistic basis of diurnal variation in N2O emissions and use modelling approaches to quantify how this diurnal variation contributes to uncertainty in N2O emission factors used for GHG inventory reporting. Our aim is to enable more accurate GHG inventory reporting and more effective testing of mitigation strategies for agricultural N2O emissions. Our work has demonstrated that N2O emissions can vary diurnally in fertilised soils with emissions peaking in mid-afternoon. Soil N2O emissions are conventionally measured at a single time of day, leading to significant errors when measurements are scaled up to annual emission estimates. Whilst the existence of diurnal N2O variation is generally accepted, the underlying mechanisms are poorly understood. Greater daytime N2O emissions are typically attributed to increased microbial activity with increasing temperature. However, our recent research suggests light intensity is also important. We hypothesise that this is not a direct effect of light intensity, but rather differences in plant metabolism (photosynthesis and root exudation) between day and night altering soil properties (e.g. carbon availability and oxygen) and so promoting diurnal variation in N2O. It is only recently that we have been able to make these conclusions due to major technological advances that allow us to measure N2O emissions near-continuously from multiple locations over day-night cycles. Supported by this technology we will investigate the importance, drivers and mechanisms of diurnal N2O variation through four work packages. We will: 1. Conduct field experiments over whole crop life-cycles to quantify how diurnal N2O emissions vary with management practices and soil physical properties (WP1); 2. Construct outdoor mesocosms with soil temperature control and shading treatments to determine to what extent temperature and light intensity drive diurnal variations in N2O emissions (WP2). 3. Conduct laboratory experiments to identify the mechanisms by which plant metabolism affects soil nitrogen cycling and amplifies daytime N2O emissions (WP3) 4. Quantify how diurnal variation in N2O emissions affects the accuracy of national GHG inventory reporting for agriculture and use Bayesian modelling to improve the accuracy of N2O emission factors by accounting for diurnal variability (WP4). The outcomes of the project will enable diurnal N2O variation to be factored into tools and models for reporting and predicting agricultural GHG emissions and will enable more accurate testing of agricultural N2O mitigation strategies.
Period of Award:
1 Jun 2021 - 30 Nov 2024
Value:
£321,257 Lead Split Award
Authorised funds only
NERC Reference:
NE/V000624/1
Grant Stage:
Awaiting Event/Action
Scheme:
Standard Grant FEC
Grant Status:
Active
Programme:
Standard Grant

This grant award has a total value of £321,257  

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FDAB - Financial Details (Award breakdown by headings)

DI - Other CostsIndirect - Indirect CostsDA - InvestigatorsDI - StaffDA - Estate CostsDI - T&SDA - Other Directly Allocated
£58,335£100,340£16,750£101,014£21,852£11,627£11,341

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