Soil Nitrogen Sorption Using Charcoal and Wood Ash
Abstract
:1. Introduction
2. Acidic Soils of Malaysia
3. Soil Acidification
4. Forms of Nitrogen in Soil-Plant Systems
5. Nitrogen Fractions and Pools in Soils
6. Soil Organic Nitrogen
7. Soil Inorganic Nitrogen
8. Soil Inorganic Nitrogen (Nitrate-Nitrogen)
9. Soil Inorganic Nitrogen (Ammonium-Nitrogen)
10. Nitrogen as a Fertiliser
11. Urea
12. Role of Nitrogen in Crops Productivity
13. Nitrogen Availability in Soils
14. Factors Affecting Nitrogen Availability to Crops
15. Nitrogen Transformation in Soil-Crops Systems
16. Mineralisation and Immobilisation
17. Nitrification
18. Denitrification
19. Volatilisation
20. Leaching
21. Crop Removal, Soil Erosion and Runoff
22. Nitrogen Use Efficiency
23. Factors Affecting Nitrogen Use Efficiency
24. Ammonium Adsorption and Desorption
25. Kinetics of Sorption Model
26. Adsorption Isotherm
27. Types of Spectroscopy
28. Ashes and Their Chemical Composition
29. Properties of Ashes
30. Use of Ashes in Agriculture
31. Mechanism of Bark Ash on the pH of Tropical Acid Soils
32. Charcoal
33. Charcoal Porosity
34. Charcoal as an Amendment That Retains Nutrients in Agriculture
35. Nutrient Sorption Mechanism of Charcoal
36. Water Retention Mechanism of Charcoal
37. Nitrate Retention Mechanism by Charcoal
38. Ammonium Retention Mechanism by Charcoal
39. Adverse Effect of Charcoal as Soil Amendment
40. Humic Substances
41. Humic Acids
42. Fulvic Acids
43. Humin
44. Changes of Carbon to Nitrogen
45. Current Challenges in Using Charcoal and Wood Ash as Adsorbents
46. Conclusions
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Acknowledgments
Conflicts of Interest
References
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Fertiliser | % Nitrogen | Composition |
---|---|---|
Ammonium sulfate | 20.5 | (NH4)2SO4 |
Calcium nitrate | 16 | Ca(NO3)2 |
Urea | 45 | (NH2)2CO |
Anhydrous ammonia | 82 | NH3 |
Diammonium phosphate | 20 | (NH4)2HPO4 |
Ammonium polyphosphate | 10–15 | (NH4PO3)n |
Urea ammonium nitrate | 28–32 | (NH2)2CO, NH4NO3 |
Name | Chemical Formula | Oxidation State |
---|---|---|
Nitrate | NO3− | +5 |
Nitrogen dioxide [g] | NO2 | +4 |
Nitrite | NO2− | +3 |
Nitric oxide [g] | NO | +2 |
Nitrous oxides [g] | N2O | +1 |
Dinitrogen [g] | N2 | 0 |
Ammonia [g] | NH3 | −3 |
Ammonium | NH4+ | −3 |
Organic N | RNH3 | −3 |
Factor | Will Increase N2O or N2 |
---|---|
NO3− or NO2− | Increasing oxidant |
Oxygen | Increasing oxygen |
Carbon | Decreasing C availability |
pH | Decreasing pH |
H2S | Increasing Sulfide |
Temperature | Decreasing temperature |
Enzyme status | Low N2O reductase activity |
Kinetic Models | Equation | Plot | Reference |
---|---|---|---|
Pseudo-first order | log(qe − qt) vs. t | [175] | |
Pseudo-second order | vs. t | [172,175] | |
Intra-particle diffusion | qt vs. t0.5 | [172] |
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Hamidi, N.H.; Ahmed, O.H.; Omar, L.; Ch’ng, H.Y. Soil Nitrogen Sorption Using Charcoal and Wood Ash. Agronomy 2021, 11, 1801. https://doi.org/10.3390/agronomy11091801
Hamidi NH, Ahmed OH, Omar L, Ch’ng HY. Soil Nitrogen Sorption Using Charcoal and Wood Ash. Agronomy. 2021; 11(9):1801. https://doi.org/10.3390/agronomy11091801
Chicago/Turabian StyleHamidi, Nur Hidayah, Osumanu Haruna Ahmed, Latifah Omar, and Huck Ywih Ch’ng. 2021. "Soil Nitrogen Sorption Using Charcoal and Wood Ash" Agronomy 11, no. 9: 1801. https://doi.org/10.3390/agronomy11091801
APA StyleHamidi, N. H., Ahmed, O. H., Omar, L., & Ch’ng, H. Y. (2021). Soil Nitrogen Sorption Using Charcoal and Wood Ash. Agronomy, 11(9), 1801. https://doi.org/10.3390/agronomy11091801