Presented by Jane Covey

1. Presented by Jane Covey

2. Methods • Mass balance analysis of nitrogen budgets in streams and lakes. • Bacterial processes and sedimentation rates indirectly obtained. • Budgets allow characterization of inputs, outputs, losses and retention of nitrogen. • Used studies of up to 40 ecosystems to quantify data.

3. Inputs • ~10,000 tons per year of atmospherically derived nitrogen (N2). • ~1300 tons entered through rain/snow. • Nitrogen fixation in groundwater/surface water and sediments by bacteria. • Most common forms: N2, NH4+, NO2-, NO3-, and organic compounds [i.e. proteins].

4. Outputs/Losses • Nitrogen removed by processes of sedimentation, denitrification and outflow [DIN/DON].

5. Nitrogen Cycle 1 • Nitrogen moves downstream bound by processes released moves farther down. • “Nutrient spiraling” refers to the process above. • Processing involves: ‘chemical ionic transformations, sorption and desorption, and metabolically mediated uptake and assimilation by biota’.

7. Nitrogen Cycle 2 • Velocity of nitrogen can equal stream velocity, but usually much slower. • “Spiralling length” {S}=average distance an atom travels in 1 cycle. • Spiralling length indicates which nutrient is limiting. The shorter the length, the more it is in demand. • The cycle is controlled by biologic materials for growth and oxidation-reduction reactions.

9. Nitrogen Cycle 3 • DIN: NO3-, NO2-, NH4+. Ammonia (NH4+) concentrations stay relatively low in natural systems [<1.5%]. • Polluted systems contain anywhere from 15 to >80 % DIN. • Concentrations of nitrogen are higher when vegetation is dying or dormant. • Stream margins and the riparian zone control DIN interactions between stream and groundwater.

10. http://www.macroevolution.net/nitrogen-cycle-diagram.html

11. Nitrogen Cycle 4 • DON: majority of dissolved nitrogen in systems, averaging between 40-90% globally. • PON: adsorbed ammonia/nitrogen adsorbed to particles. • Riparian, parafluvial and hyporheic zones as major sources of ammonium and DON to streams. • Microbes (bacteria, fungi, algae) within streams uptake DON and vary the concentrations.

13. Nitrogen Cycle 5 • Nitrogen (various) alteration by: fixation, assimilation and reduction of nitrate to N2 [denitrification]. • Oxidation + reduction+ photosynthesis= use by algal blooms, bacteria and plants. • Nitrification: NH4+NO2-NO3-[IN] N2ON2 • Nitrification/denitrification occur simultaneously/reciprocally in hyporheic zone.

17. Variables • Flooding can cause changes in nitrogen concentrations. • Loss of biota reduces nitrogen retention, recovery increases retention. • Agriculture [fertilizers], sewage, industrial waste, atmosphere pollution can throw off concentration of DON/DIN. • Overloading systems with phosphorous can make nitrogen a limiting nutrient.

18. Results • Storage in woody debris/vegetation (59-90%) of forested systems. • Storage in algae/autochthonous detritus (93%) of desert systems. • Steady state assumes inputs = outputs. • Retention is high among low order systems, intensively recycled by organisms and were <50-60 micrograms/L.

20. Discussion questions/ Answers * Considering nitrogen in an ecosystem, is it considered a' non-conservative' substance? How might nitrogen be considered a limiting factor in an ecosystem and what role do humans play in the cycle?