Dissertation
Nitrogen Dynamics and Greenhouse Gas Production in Yaqui Valley
Doctor of Philosophy (PhD), Stanford University
2003
Abstract
Agricultural runoff is thought to constitute a globally important source of the greenhouse gas nitrous oxide (N 2 O), and may also be a significant source of the greenhouse gases methane (CH 4 ) and carbon dioxide (CO 2 ). However, production of N2 O, CH4 , and CO 2 in polluted aquatic systems is poorly understood and scarcely reported, especially in low-latitude (0-30º) regions where rapid agricultural intensification is occurring. We measured N 2 O, CH4 , and CO 2 emissions, dissolved N 2 O concentrations, and factors likely to control rates of greenhouse gas production in Yaqui Valley drainage canals receiving agricultural and mixed agricultural/urban inputs. Average per-area N2 O flux in both purely agricultural and mixed urban/agricultural drainage systems (16.5 ng N2 O-N cm -2 hr-1 ) was high compared to other fresh water fluxes, and extreme values ranged up to 244.6 ng N2 O-N cm -2 hr-1 . These extremely high N2 O fluxes occurred during green algae blooms, when organic carbon, nitrogen, and oxygen concentrations were high, and only in canals receiving pig-farm and urban inputs, suggesting an important link between land-use and N 2 O emissions. N2 O concentrations and fluxes correlated significantly with water column concentrations of nitrate, particulate organic carbon and nitrogen, ammonium, and chlorophyll a. A multiple linear regression model including ammonium, dissolved organic carbon, and particulate organic carbon was the best predictor of [N2 O] (r 2 = 52%). Despite high per-area N 2 O fluxes, our estimate of regional N 2 O emission from surface drainage (20,869 kg N2 O-N yr-1 ; 0.046% of N-fertilizer inputs) was low compared to values predicted by algorithms used in global budgets. All canals where we measured CO 2 were net-heterotrophic. CH4 fluxes, though variable (range: -1372 – 3990 mg CH4 -C m -2 d-1 ), were generally quite high (mean: 3208 ng-C cm -2 hr-1 ) compared with fluxes from similar systems in other locations. C gas evasion from streams was several times greater than stream export of organic C via lateral transport. During algae bloom conditions we observed rapid and complete oxidation and reduction of an entire drainage canal. This has not previously been reported and may have important implications for in-stream transformations and downstream transfer of N, iron, manganese, and sulfur as well as the production of N 2 O, CH4 , and CO2 .
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Details
- Title
- Nitrogen Dynamics and Greenhouse Gas Production in Yaqui Valley
- Creators
- John Harrison - Washington State University, Environment, School of the (CAS)
- Contributors
- Pamela Matson (Advisor) - Stanford UniversityRobert Dunbar (Committee Member)Scott Fendorf (Committee Member)Peter Vitousek (Committee Member)
- Awarding Institution
- Stanford University
- Theses and Dissertations
- Doctor of Philosophy (PhD), Stanford University
- Format
- pdf
- Number of pages
- 119
- Identifiers
- 99900667381401842
- Language
- English
- Resource Type
- Dissertation
- Academic Unit
- Department of Geological and Environmental Sciences