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CATION EXCHANGE CAPACITY

CATION EXCHANGE CAPACITY. and PLANT NUTRITION. Cation Exchange Capacity (CEC). Clay Particles and Humus affect chemical properties of soil complex structures with many negative charge sites negative charge sites attract positive ions called cations. CEC.

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CATION EXCHANGE CAPACITY

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  1. CATION EXCHANGE CAPACITY and PLANT NUTRITION

  2. Cation Exchange Capacity (CEC) Clay Particles and Humus • affect chemical properties of soil • complex structures with many negative charge sites • negative charge sites attract positive ions called cations

  3. CEC Negative charge sites are referred to as . . . Cation exchange sites + attract cations from soil solution+

  4. CEC Force of attraction is called: Adsorption similar to force of a magnet holding iron filings

  5. CEC Cations can move on and off particles . . . when one leaves, another replaces it This process is called cation exchange, and cations involved are said to be exchangeable

  6. CEC The number of sites that a colloid (small particle) of charged clay or humus (micelles) contains is measured by the: Cation Exchange Capacity expressed in mEq/100g Note: newer units expressed in cmolc/kg

  7. CEC may range from: 2.0 mEq/100g for sand to > 50 mEq/100g for some clays humus 100-300 mEq/100g

  8. CEC How fertile can a soil be? Does applying more fertilizer always provide more nutrients to plants? How much of the CEC is actually filled with cations?

  9. CEC The proportion of the CEC occupied by basic (+) nutrients such as Ca, Mg, K, Na, is called: Percent Base Saturation and is an indication of the potential CEC of a given soil

  10. CEC Estimations that > 99% of cations in soil solution are adsorbed . . . does not mean that percent base saturation is 99%

  11. CEC Example: A soil with CEC of 10 mEq/100g has 6 mEq/100g of bases (Ca, Mg, K, Na) occupying exchange sites What is the percent base saturation of the soil?

  12. CEC 6 mEq/100g bases 10 mEq/100g sites = 60 % base saturation

  13. CEC Cation Exchange is determined by: 1) strength of adsorption 2) law of mass

  14. CEC Strength of adsorption is as follows: H+ and Al3+ > Ca2+ > Mg2+ > K+ > NH4+ > Na+

  15. CEC Law of Mass the more of one ion available, the greater the chance of adsorption

  16. NUTRITION There are at least 17 elements recognized as essential nutrients for plants; we will recognize 18 elements: C, H, O, P, K, N, S, Ca, Fe, Mg, Mn, Mo, Cl, Cu, Zn, B, Co, Ni

  17. NUTRITION Nutrients grouped into 2 categories according to the relative amount used by plants: Macronutrients – major elements; large amounts Micronutrients – minor elements; small amounts Both are essential for optimal plant production

  18. NUTRITION Note: C, H, O . . . essential elements not considered in nutritional studies; Why?

  19. NUTRITION > 95% of plant dry wt. from C, H, O; (balance from macro, micro and other elements)

  20. NUTRITION Except for C, H, O . . . - Nitrogen (N) is present in greatest concentrations; - Plants respond readily to Nitrogen (N)

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