Ammonia Volatilization from Urea Fertilizer
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Ammonia volatilization from urea David E. Kissel University of Georgia Overview • • • • • • • Evolution of Urea consumption Definitions Urea Dissolution and Diffusion Urea Hydrolysis Ammonia Volatilization Research Results Summary USA Evolution of N Fertilizers Consumption 21% Urea Ammonium nitrate 1973 / 74 2004 / 05 Nitrogen solutions Anhydrous ammonia Total compound N 0 1 2 3 4 5 Millions of tonnes www.fertilizer.org Overview • • • • • • • Evolution of Urea consumption Definitions Urea Dissolution and Diffusion Urea Hydrolysis Ammonia Volatilization Research Results Summary Definitions • Dissolution: urea absorbs water and converts from solid to liquid • Hydrolysis: urea converts to ammonium (NH4+) • Diffusion: movement due to motion of molecules – Urea has no charge, diffuses easily – NH4+ has charge, diffuses slowly Overview • • • • • • • Evolution of Urea consumption Definitions Urea Dissolution and Diffusion Urea Hydrolysis Ammonia Volatilization Research Results Summary Urea Dissolution • Urea has to be dissolved before it can be hydrolyzed Urea Dissolution • Urea has to be dissolved before it can be hydrolyzed • Urea can absorb water from the atmosphere and from the soil/crop residue Urea Dissolution • Urea has to be dissolved before it can be hydrolyzed • Urea can absorb water from the atmosphere and from the soil/crop residue • Absorption of water from the atmosphere depends on relative humidity (RH) Urea Dissolution • Urea has to be dissolved before it can be hydrolyzed • Urea can absorb water from the atmosphere and from the soil/crop residue • Absorption of water from the atmosphere depends on relative humidity (RH) • Critical relative humidity (CRH) is the RH at which urea dissolves 90 16 CRH 85 14 80 12 75 10 70 8 65 6 60 20 Solubility 40 60 80 100 o Air Temperature ( F) 4 120 Urea Solubility (lb/gallon of water) Critical Relative Humidity for Urea (%) Effect of Temperature on CRH and Water Solubility of Urea Urea dissolution and diffusion RH > CRH (80%) www.agrium.com Crop residue Urea Urea Dry Soil Urea Urea dissolution and diffusion www.agrium.com Crop residue Urea 1/2 inch Urea Urea Urea Wet Soil Urea Urea Crop residue Urea 2 inches Urea Urea Urea Urea Urea Urea Diffusion into Soil Urea Diffusion Depth Urea Urea Urea Urea Urea • Determined by soil moisture Urea Diffusion into Soil (after 10 days) Urea Concentration in Soil (ppm) 0 Soil Depth (mm) 10 20 30 40 50 0 100 200 300 400 Wetter Drier 500 600 700 Overview • • • • • • • Evolution of Urea consumption Definitions Urea Dissolution and Diffusion Urea Hydrolysis Ammonia Volatilization Research Results Summary Urea Hydrolysis Urea +2 H+ Urease enzyme 2 NH4+ • Urease is derived from crop residues and soil microorganisms Urease inhibitor Crop residue Urea Urea Urea Urea Urea Urea Overview • • • • • • • Evolution of Urea consumption Definitions Urea Dissolution and Diffusion Urea Hydrolysis Ammonia Volatilization Research Results Summary NH3 Volatilization Process Atmosphere NH3 NH3 Hydrolysis NH3 NH3 NH3 NH3 Urea + H+ NH4 + Soil solution NH3 NH3 Soil air NH3 (gas) Clay OM NH4+ NH4+ NH4+ NH4+ (aq) NH3 (aq)+ H+ Equilibrium NH3 (as % of Total Ammoniacal N) Effect of soil pH on NH3 as % of Total N 30 o 68 F 25 20 15 10 5 0 5 6 7 Soil pH 8 9 NH3 Volatilization Process Atmosphere NH3 NH3 Hydrolysis NH3 NH3 NH3 NH3 Urea + H+ NH4 + Soil solution NH3 NH3 Soil air NH3 (gas) Clay OM NH4+ NH4+ NH4+ NH4+ (aq) NH3 (aq)+ H+ Equilibrium Low Buffering Capacity -1 NH3 Loss (kg N ha ) 12 •Increase in soil pH depends on soil H+ buffering capacity 8 4 High Buffering Capacity 0 Low Buffering Capacity •Higher clay and OM contents lead to higher soil H+ buffering capacity Soil pH 9 8 High Buffering Capacity 7 Ferguson et al. (1984) 6 0 2 4 6 8 10 12 Days Since Urea Application Atmosphere Urea hydrolyzes on the soil surface Urea Urea Urea Urea NHNH + NH33 NH33 + NH + NH 4 4 4 + NH + + 4 + NH + NH NH 4 4 NH 4 NH 4 NH H+ H + 3 3 NH33 NH3 NH3 3 H+ H+ ½ inch H+ H+ H+ + HCEC pH 6 7 8 9 Urea hydrolyzes below the soil surface Urea Urea Urea Urea Urea Urea Urea Urea NH + + NH + NH 4 4 4 + NH + + 4 + NH + NH NH 4 4 NH4 4 H+ H + H+ H+ NH3 2 inches H+ H+ H+ H+ CEC pH 6 7 Effect of Temperature on NH3 Volatilization Temperature NH3 NH3 NH3 NH3 NH3 NH3 Soil NH3 NH3 ½ inch Urea NH4+ NH3 + H+ Effect of Temperature on Urea Hydrolysis Relative Urease Activity 6 5 4 3 2 1 Gould et al. (1973) 0 30 40 50 60 70 80 Temperature (oF) 90 100 110 Effect of Temperature on NH3 Volatilization Temperature NH3 NH3 NH3 NH3 NH3 NH3 Soil NH3 NH3 ½ inch Urea NH4+ NH3 + H+ NH3 (as % of Total Ammoniacal N) Effect of Temperature on % of NH3 35 30 pH = 8.5 25 20 15 10 5 0 30 40 50 60 70 80 Temperature (oF) 90 100 110 Effect of Temperature on NH3 Volatilization Temperature NH3 NH3 NH3 NH3 NH3 NH3 Soil NH3 NH3 ½ inch Urea NH4+ NH3 + H+ Relative Driving Force for Conversion of Aqueous NH3 to Gaseous NH3 Effect of Temperature on Conversion of Aqueous NH3 to Gaseous NH3 5 4 3 2 1 30 40 50 60 70 80 Temperature (oF) 90 100 110 Effect of Temperature on NH3 Volatilization Temperature NH3 NH3 NH3 NH3 NH3 NH3 Soil NH3 NH3 ½ inch Urea NH4+ NH3 + H+ Effect of Wind Speed on NH3 Volatilization Atmosphere NH NH33 NH NH33 NH3 NH NH33 NH3 Wind speed NH33 NH3 NH3 NH NH33 NH NH33 NH3 NH NH33 NH3 NH33 Soil NH3 NH3 ½ inch Urea NH4+ NH3 + H+ 20 UAN UREA Nitamin Replication I 15 51mm 5 0 20 5 15 10 51mm UAN UREA Nitamin Replication III 15 51mm 5 0 0 Low 3 2 0 00:00:00 0 10 4 1 5 20 High Replication II UAN UREA Nitamin Wind Speed (m s-1) Ammonia Loss (% of Applied N) 10 20 40 60 80 100 120 Days After Application 08:00:00 16:00:00 Time 00:00:00 Optimum Conditions for Volatilization • • • • • Small diffusion depth into soil RH > CRH High temperature High wind speed Low pH buffering capacity Overview • • • • • • • Evolution of Urea consumption Definitions Urea Dissolution and Diffusion Urea Hydrolysis Ammonia Volatilization Research Results Summary Nitamin® UAN Urea 50 40 30 20 10 Rainfall 50 Rainfall (mm) Temp = 47oF 0.4 Soil water content 40 0.3 30 0.2 20 0.1 10 0 20 40 60 80 100 Days after application 120 Soil water content (g g-1) NH3 loss (% of applied N) Urea Applied to Pasture - Fall 2004 Nitamin® UAN Urea 50 40 Temp = 63oF 30 20 10 Rainfall Rainfall (mm) 50 Soil water content 0.4 40 0.3 30 0.2 20 0.1 10 0 20 40 60 Days after application Soil water content (g g-1) NH3 loss (% of applied N) Urea Applied to Pasture – Spring 2005 Atmosphere Urea Urea NH + 4 Urea Urea4+ NH Urea + Urea NH 4 NH3 Clay OM NH4+ (aq) NH3 Equilibrium (aq) + H+ Nitamin® UAN Urea 50 40 Temp = 62oF 30 20 10 Rainfall Rainfall (mm) 50 Soil water content 0.4 40 0.3 30 0.2 20 0.1 10 0 20 40 60 Days after application Soil water content (g g-1) NH3 loss (% of applied N) Urea Applied to Pasture - Fall 2005 Time of RH > CRH (h) Time of RH above CRH in the first 30 d 25 20 15 10 5 0 0 5 10 15 20 25 30 Days after application 63days % Total: RH > CRH = 19 Atmosphere RH > CRH (80%) NH3 NH3 NH3 NH3 NH3 NH3 NH3 NH3 NH3 NH3 NH3 Urea + NH NH3 NH3 NH3 NH3 NH3 + NH Urea + 4 NH + Urea NH 4NH + 4 NH 4 4 NH + 4 4 Fescue thatch + Soil water content (0.07 g g-1) Permanent wilting point (0.04 g g-1) Nitamin® UAN Urea 50 40 Temp = 69oF 30 20 10 Rainfall Rainfall (mm) 50 Soil water content 0.4 40 0.3 30 0.2 20 0.1 10 0 20 40 60 Days after application 80 Soil water content (g g-1) NH3 loss (% of applied N) Urea Applied to Pasture – Spring 2006 Atmosphere Urea + NH4Urea Urea Urea NH4+ Urea UreaNH4+ NH3 NH3 NH3 NH3 NH3 NH3 NH4 NH3 + (aq) content Soil water CEC NH3 NH3+ H -1 (aq) (0.15 g g ) Equilibrium Field capacity (0.18 g g-1) + Summary of Pasture Results Ammonia volatilization losses under field conditions Fall 2004 Fertilizer Spring 2005 Fall 2005 Spring 2006 --------------- Ammonia loss (% of applied N) ----------------- Urea 19 a* 12 a 46 a 24 a UAN 6b 13 a 33 b 18 a Nitamin® 6b 14 a 34 b 18 a •Within a column, values followed by the same letter are not significantly different according to Fisher’s LSD at p=0.05 Summary for Pastures/No-Till Dry Soil, Dry Residue, RH < CRH: OK Dry Soil, Dry Residue, RH > CRH: not OK Wet Soil, Wet Residue: not OK • Apply on dry soil, dry residue, expected low RH, and hope for 1 inch of rain whenever it rains. • Apply on wet soil if 1 inch rain/irrigation is expected. Summary for Clean-Till Crops Dry Soil: OK Wet Soil: not OK • Apply on dry soil and hope for 1 inch of rain whenever it rains. • Apply on wet soil if 1 inch of rain/irrigation is expected. Summary for Pastures/Crops Knifed or disked in Dribbled Broadcast • Knifed of disked in better than Dribbled • Dribbled better than Broadcast Urea Applied to Pine Plantations NH3 Loss (% of N Applied) 35 Mar 3 - Apr 2002 12 March 1412, – April 30 (59oF) 25 20 11 mm 4 mm 15 0 mm 10 5 0 0 5 10 15 20 25 Rain Days After Urea Application 30 35 NH3 Loss (% of Applied N) Urea Applied to Pine Plantations May 2 - May 31, 2002 60 40 mm 40 0 mm 20 mm 20 Rain 66oF 0 0 5 10 15 20 25 30 Days After Application 35 Cumulative NH3 Loss (% of Applied N) Laboratory Results (77oF, 90% RH) 20 20 mm before urea 20 mm right after urea 20 mm 1 day after urea 20 mm 3 days after urea 15 10 5 5 mm rain added to all treatments 0 0 5 10 15 20 25 Days After Urea Application 30 Pine needle photo Urea www.microscopyu.com NH4 NH4+ + CEC CEC Organic Layer Pine needle photo NH3 NH3 NH3 NH3 NH3 NH3 NHUrea 3 NH3 Urea NH4 NH4 +NH4+ + CEC NH4 www.microscopyu.com + NH4+ Organic Layer CEC Summary for Pine Plantations Dry Forest Floor, RH < CRH: OK Dry Forest Floor, RH > CRH: not OK Wet Forest Floor: not OK • Apply on dry forest floor, with expected low RH, and hope for 1 inch of rain whenever it rains. • Apply on wet forest floor if 1 inch rain is expected. 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