description
- Atmospheric reactive nitrogen oxide gases (NOy = NO + NO2 + HONO + ...) are coupled to Earth's nitrogen cycle through an intricate network of interactions between anthropogenic activity (primarily combustion), soil nitrogen, and soil microbial activity. The biogeochemistry of soil nitrogen emissions is traditionally thought to be dominated by nitrogen gas (N2) and nitrous oxide (N2O); however, satellite, modelling, and laboratory studies show NOy emissions from soil can be of greater magnitude than these more commonly measured nitrogen gases. NOy are important in atmospheric chemistry as precursors to ozone (O3) and play a key role in the formation of acid rain. NOy are also considered secondary air pollutants - known to worsen asthma and bronchitis, especially in adolescent and geriatric populations. In addition to anthropogenic sources, NOy gases are produced from natural non-point sources including soil (24% of total NOy emissions), wildfires (19%), and lightning (13%). However, very little is known about NOy fluxes from these natural sources even though they account for 50% of all atmospheric NOy - with this percentage increasing as vehicle and industry emissions continue to decline. Importantly, there is a critical lack of information regarding biogenic (microbiologically derived) production mechanisms, resulting in inaccurate NOy-coupled climate model projections. This can be primarily attributed to a lack of understanding regarding the formation of major NOy species, such as nitrogen dioxide (NO2) and nitrous acid (HONO). We suspect there are yet undiscovered NOy-producing pathways, catalysed by a vast array of microbes from all three domains of life. Our hypothesised mechanisms are derived from human physiology, where NOy species are known to be important signalling molecules. We will explore these mechanisms in agronomic soils, as soils are the largest natural source of NOy gases, and within an agronomic context as our preliminary work has shown that these soils produce significantly more NOy than other terrestrial systems such as grasslands and woodlands. We will further define agronomic-NOy with field trials of a major UK commercial crop (Triticum), including four cultivars with differing above- and belowground traits. It will be crucial to define NOy soil emissions from these different cultivars, as varying plant traits, such as specific root length, can influence the soil N-cycle microbiome - which will inevitably influence NOy emissions. Other important variables will also be explored, including fertiliser application and spatial variability of NOy flux. Importantly, we will also attempt to determine the role of soil iron and iron speciation on N-cycle community composition and NOy fluxes. Soil iron is an important aspect of our theoretical NOy mechanism - stimulating the production of reactive oxygen species, which is a key reactant in the production of NOy. We will source soil with differing iron content from various farms throughout England to be used in wheat mesocosms studies. Soil NOy fluxes will be measured and connected to mineralogical characteristics and the N-cycle community size. Overall, this project will determine fundamental knowledge on the biogenic production mechanisms of major NOy species, provide direct soil NOy flux measurements from a major global crop, and lead to a better understanding of coupled carbon-nutrient-mineral cycling in soil. Furthermore, this work represents a major step change in the understanding of soil nitrogen dynamics, will be one of the first to couple shotgun metagenomics and culture-dependent methods to atmospheric chemistry processes, and will represent a major advancement in atmospheric accounting of NOy.