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Soil Biogeochemical Cycles

Explore the role of biota in capturing and storing soil nutrients and learn how they are released to plants when needed. Understand the biogeochemical cycles of carbon, nitrogen, and phosphorus in soil. Discover the impact of synthetic fertilizers on plant-soil interactions and explore strategies for sustainable soil management.

mikeburns
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Soil Biogeochemical Cycles

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  1. Soil Biogeochemical Cycles Carbon, Nitrogen, Phosphorus

  2. Recall “biotic regulation” • Biota capture and store soil nutrients and return them to plants when they need them • In biotic regulation, nutrients are held in resistant forms, not readily lost from soil • When plants need nutrients, they stimulate soil biota to release the nutrients • Synthetic fertilizers cause physiological changes in plants that make them withhold energy from soil biota

  3. 24/103 required by organisms Macronutrients: C,H,N,O,P,S Micronutrients

  4. BIOGEOCHEMICAL CYCLES The complete pathway that a chemical element takes through the biosphere, hydrosphere, atmosphere and lithosphere.

  5. Elements transferred between compartments (pools) Active: accessible to living things Storage: inaccessible

  6. Soil Carbon Cycle

  7. CARBON CYCLE atmosphere photosynthesis respiration biosphere

  8. Plant residues Applied organic materials GAINS Soil organic carbon LOSSES Respiration Plant removal Erosion

  9. Pools (compartments) of soil organic matter: (categorized by susceptibility to microbial respiration) 1. Active C:N 15:1 – 30:1 1-2 years readily accessible to microbes; most of mineralizable N 10 – 20% of total 2. Slow C:N 10:1 – 25:1 15-100 yrs food for autochthonous microbes ; some mineralizable N 3. Passive C:N 7:1 – 10:1 500-5000 yrs colloidal; good for nutrient and water-holding 60 -90% of total

  10. Soil management may help curb greenhouse effect due to carbon dioxide emissions pre-Industrial Revolution: 280 ppm CO2 post: 370 ppm 0.5% increase per year Causes: 1. Fossil fuel burning 2. Net loss of soil organic matter By changing balance between gains and losses, may limit loss of OM…how?

  11. How? 1. Restore passive fraction in soils that are degraded. -sequesters carbon for long time 2. Switch to no-till practices 3. Convert to perennial vegetation

  12. Cornfield in warm, temperate climate Net loss of carbon

  13. Soil Nitrogen Cycle

  14. Atmosphere 78% nitrogen • Not in directly accessible form for organisms • Made usable by fixation • Most terrestrial N in soil • 95-99% in organic compounds • Made usable by mineralization

  15. Let’s look at all components and processes in nitrogen cycle…..

  16. A. Nitrogen fixation 1. Atmospheric: lightning • Oxidation of N2 2. Industrial production of N fertilizer N2 + H2→ NH3 3. Biological (soil organisms) (industrial fixes 85% as much N as organisms)

  17. Biological fixation(soil organisms) Immobilization: microbes convert N2 to N-containing organic compounds Nitrogenase

  18. 2 groups of N-fixing microorganisms • Nonsymbiotic, autotrophic: (use solar energy) • Some actinomycetes • Cyanobacter (formerly known as blue-green algae) • Photosynthetic bacteria

  19. B.Symbiotic, in association with legume plants (plants supply energy from photosynthesis) 1. Rhyzobium 2. Bradyrhizobium Infect root hairs and root nodules of legumes

  20. Symbiosis: mutualistic: plants provide energy, bacteria provide ammonia for synthesis of tissue Energy-demanding process: N2 + 8H+ + 6e- + nitrogenase → 2NH3 + H2 NH3 + organic acids → amino acids → proteins

  21. B. Mineralization (ammonification) Heterotrophic microorganisms Decomposition Organic N compounds broken down to ammonia; energy released for microorganisms to use Organic N + O2→CO2 + H2O +NH3 + energy

  22. C. Nitrification Oxidizes ammonia to nitrate; 2 step oxidation process: 1. Nitrosomonas: NH3→NO2- (nitrite) + energy 2. Nitrobacter: NO2-→NO3- (nitrate) + energy

  23. D. Denitrification Completes N cycle by returning N2 to atmosphere (prevents N added as fertilizer from being “locked” in roots and soil) Requires energy; Reduction of nitrate/nitrite NO2 or NO3 + energy→N2 + O2 (many steps) Denitrifying bacteria and fungi in anaerobic conditions

  24. Arbuscular mycorrhizae • Involve 2/3 of plant species. • Unlike most fungi, the AM fungi get their supply of sugars for energy and growth from their plant partner and not from the decomposition of organic matter • AM fungi thrive on decomposing organic matter and obtain large amounts of nitrogen from it. • The fungus itself is much richer in N than plant roots, and calculations suggest that there is as much nitrogen in AM fungi globally as in roots. • Since fungal hyphae (the threads of which the fungus is composed) are much shorter-lived than roots, this finding has implications for the speed with which nitrogen cycles in ecosystems.

  25. Phosphorus Cycle

  26. Phosphorous Cycle • P often limiting factor for plants: • low in parent materials • inclination to form low-soluble inorganic compounds • After N, P is most abundant nutrient in microbial tissue

  27. Differs from N cycle 1. No gaseous component 2. N goes into solution as nitrate • Stable, plant-available But P reacts quickly with other ions and converts to unavailable forms

  28. Available P in soil solution: • as H2PO4- or HPO4-2 ion • Microbes constantly consume and release P to soil solution

  29. Unavailable forms of P depend on soil pH: • High pH: calcium phosphate CaHPO4 • Stable in high pH • Soluble in low pH • E.g., rhizosphere, so plants can get it • Can be transformed to less-soluble Ca-P form (apatite) • Low pH: iron and aluminum phosphates • Highly stable • Slightly soluble in low pH

  30. Role of mycorrhizae in P cycle: Can infect several plants: Hyphae connect plants ; conduits for nutrients Fungi get E from plant ‘s photosynthesis.

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