1 / 28

Soil fertility considerations in direct seeding

Soil fertility considerations in direct seeding . Rich Koenig, Associate Scientist/Extension Soil Fertility Specialist. Discussion Topics. Soil changes as a result of direct seeding (compared to conventional tillage) Implications of these changes on nutrient management Nitrogen mineralization

nan
Télécharger la présentation

Soil fertility considerations in direct seeding

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Soil fertility considerations in direct seeding Rich Koenig, Associate Scientist/Extension Soil Fertility Specialist

  2. Discussion Topics • Soil changes as a result of direct seeding (compared to conventional tillage) • Implications of these changes on nutrient management • Nitrogen mineralization • Cold, wet soils and nutrient placement • Enhanced immobilization and volatilization potential • Other • Other topics and recent research results, as time permits • Chloride • Phosphorus • Split nitrogen applications • Nitrogen management for wheat

  3. Physical changes • Improved aggregation (formation of clods) • Increased density (compaction) in soils prone to this problem (fine textures) • Reports of short term increase in compaction problem • Aggregates eventually become more stable and compaction problem eases • Improved water infiltration and percolation • Reduced runoff, erosion, etc.

  4. Physical changes • Stratification of residue • Layering on the surface vs. incorporation • Higher soil moisture, particularly at the surface • Lower soil temperature due to the insulating effect of residue and higher moisture • Lower oxygen concentration at the surface • Collectively, cool, wet soils limit biological and root activity, and nutrient uptake by plants

  5. Biological changes • Overall higher microbial biomass (more/larger organisms out there) • Different groups of microbes • Increase in fungi biomass compared to bacteria • Mycorrhizae fungi and associated benefits on nutrient uptake • Perhaps a lower level of microbial activity • Slower and different metabolism • Physical effects – residue not in contact with soil • Different location of microbes and activity (in residue layer rather than in the mineral soil)

  6. Biological changes • Lower nitrogen mineralization rates per unit of organic matter (remember: biological process) • Lower surface temperature • High moisture and lower oxygen levels • Crop residues not in contact with the soil and not physically broken down by tillage • Potential for immobilization and volatilization with broadcast nitrogen • Root growth and nutrient availability issues with lower temperatures

  7. Chemical changes • Short term - lower mineralization contributions to the total N supply • Eventually, an overall higher level of organic matter leading to greater mineralization contributions to the total N supply • Nutrient and pH “stratification”or layering • Phosphorus, potassium, other immobile nutrients • Many unknowns here

  8. Stratification of acidity under direct seeding 6 inches No treatment 6 inches Broadcast lime

  9. Aside: how fast are changes reversed in a return to tillage? • Immediately for soil temperature and moisture conditions • As little as 2 months to completely reverse soil aggregation and other physical improvements • Immediate increases in nitrogen mineralization, carbon dioxide evolution and perhaps nitrous oxide emissions

  10. Implications

  11. Nitrogen mineralization • Issue #1 • Initial conversion to direct seeding results in the accumulation of organic matter with a required accumulation of organic nitrogen • Consider this: • 1% organic matter in 1 foot of soil • = ~40,000 lb organic matter/acre • = ~15,000 lb organic carbon/acre • = ~1,500 lb organic nitrogen/acre • Transition period varies with environment and cropping system (5-10+ years commonly quoted)

  12. Example of different scenarios

  13. Nitrogen mineralization • Issue #2 • Rates of organic matter mineralization are lower due to cooler and wetter (lower oxygen) soil conditions • Research • No-till mineralization rates were 44% of conventional till rates in a Missouri corn rotation • No-till mineralization rates were 52% of conventional till rates in canola residue from Canada • 3.4x higher rates of mineralization with conventional compared to no till in Georgia with sourghum • Larger differences in residue of cereals than legumes

  14. Nitrogen mineralization • How to deal with this? • Options during the transition to direct seeding • Don’t take the mineralization credit • Don’t include surface organic residues in soil samples • Use a lower N mineralization estimate • 10 to 15 lb N for each % organic matter up to 3% (compare to 20 lb N for each % in conventional till) • Factor in immobilization

  15. Mineralization in Palouse conventional till

  16. Nitrogen mineralization • After the transition to direct seeding • Monitor soil organic matter levels (now need to include surface residues) • Look for stable numbers over time = completed the transition • Continue to use lower factor for N mineralization per % organic matter

  17. Colder and wetter soils • Reduced root growth and efficiency of nutrient uptake, especially in spring • Mycorrhizae may partially offset this effect • Emphasize the importance of subsurface banding of phosphorus and nitrogen • Emphasize the importance of starter fertilizers placed with or near the seed, especially for spring crops

  18. Immobilization and volatilization potential • Limited to surface broadcast applications of nitrogen for immobilization and urea-based forms for volatilization • Subsurface banding to place nitrogen below residue limit immobilization • Broadcasting nitrgoen when temperatures are low and precipitation is imminent to limit volatilization

  19. Direct seed fertility recommendations emphasize • Importance of soil testing • Difficulty in estimating nitrogen mineralization during the transition and later • Importance of subsurface placement of nitrogen and immobile nutrients • Importance of starter fertilizers • Some unknowns

  20. Chloride studies

  21. 2004-05 and 2005-06 Winter Wheat Chloride Studies • Comprehensive study • 2 locations: Pullman and Farmington (soil test chloride 18-19 lb/ac in top 2 feet) • 2 sources: ammonium chloride and potassium chloride • 2 application times: fall (deep band) and spring at herbicide treatment • 2 rates: 0 and 30 lb chloride/acre • 5 varieties: Falcon, Finch, Madsen, ORCF 101, Tubbs

  22. Leaf spot on Clearfirst in PNW

  23. Average chloride timing effects (p<.01)

  24. Average chloride source-rate effects No statistical difference * *Significantly different from +Cl treatments

  25. Average yield response - all site-years +9 +11 +11 Average response (bu/ac) +11 0

  26. Madsen – no chloride With chloride Finch – no chloride With chloride

  27. Flag leaf spots - 2005 Pullman study *stripe rust

More Related