Application of Zeolites in Agriculture and Other Potential Uses: A Review
Abstract
:1. Introduction
2. History and Origin of Zeolites
- -
- Crystals found from hot-spring or hydrothermal activity (reaction with basaltic lava flows);
- -
- Sediments originating from volcanic deposits in saline and alkaline lake systems;
- -
- Deposits originating in alkaline soil from volcanic sediments;
- -
- Deposits formed from marine sediments’ low-temperature or hydrothermal alteration;
- -
- Formations resulting from low-grade burial metamorphism [22].
3. Classification and Structure of Zeolites
- (a)
- Zeolites erionite and mordenite—high Si/Al ratio (from 10 to several thousands);
- (b)
- Zeolites Y—intermediate Si/Al ratio (2 to 5);
- (c)
- Zeolites A—low Si/Al ratio (between 1.0 and 1.5).
- (1)
- 14 member rings; extra-large-pore zeolites with free pore diameter of 0.8–1.0 nm;
- (2)
- 12 member rings; large-pore zeolites with free pore diameter of 0.6–0.8 nm;
- (3)
- 10 member rings; medium-pore zeolites with free pore diameter of 0.45–0.6 nm;
- (4)
- 8 member rings; small-pore zeolites with free pore diameter of 0.3–0.45 nm [46].
4. Properties of Zeolites
- ➢
- Analcite: high heat stability, 18% porosity, 2.24–2.29 g/cm3 specific gravity, 1.85 g/cm3 bulk density, 4.54 meq/g ion exchange capacity;
- ➢
- Chabazite: high heat stability, 47% porosity, 2.05–2.10 g/cm3 specific gravity, 1.45 g/cm3 bulk density, 3.84 meq/g ion exchange capacity;
- ➢
- Clinoptilolite: high heat stability, 34% porosity, 2.15–2.25 g/cm3 specific gravity, 1.15 g/cm3 bulk density, 2.16 meq/g ion exchange capacity;
- ➢
- Erionite: high heat stability, 35% porosity, 2.02–2.08 g/cm3 specific gravity, 1.51 g/cm3 bulk density, 3.12 meq/g ion exchange capacity;
- ➢
- Heulandite: low heat stability, 39% porosity, 2.18–2.20 g/cm3 specific gravity, 1.69 g/cm3 bulk density, 2.91 meq/g ion exchange capacity;
- ➢
- Mordenite: high heat stability, 28% porosity, 2.12–2.15 g/cm3 specific gravity, 1.70 g/cm3 bulk density, 4.29 meq/g ion exchange capacity;
- ➢
- Phillipsite: moderate heat stability, 31% porosity, 2.15–2.20 g/cm3 specific gravity, 1.58 g/cm3 bulk density, 3.31 meq/g ion exchange capacity.
- The behavior of ‘zeolitic’ water: high potency of hydration and dehydration [55];
- Extensive void volume and low density when dehydrated [56];
- Molecular sieve property [57];
- Stability of the crystal structure of many dehydrated zeolites when 50% volumes of the dehydrated crystals are void [58];
- In the dehydrated crystals, homogenous molecular-sized channels [32];
- Several physical properties, such as electrical conductivity [61];
- Gases and vapors adsorption [62];
- Catalytic properties [63].
5. Application of Zeolites in Agriculture
5.1. Fertilizer Efficiency
5.2. Soil Amendment
5.3. Slow Release of Herbicides
5.4. Heavy Metal Traps
5.5. Water Absorption
5.6. Gas Absorption
5.7. Antifungal Activity and Crop Protection
5.8. Photosynthesis Enhancement on Crops
5.9. Heat Stress and Sunburn of Zeolites on Crops
5.10. Aquaculture
5.11. Animal Feed Additive
- -
- Aflatoxin-sequestering effect: elimination of mycotoxin growth inhibitory effects;
- -
- Ammonia-binding effect: elimination of ammonia toxic effects produced by intestinal microbial activity;
- -
- Enhanced pancreatic enzymes activity: favorable effect on feed components hydrolysis over a wider range of pH, improved energy and protein retention;
- -
- Fecal elimination of p-cresol: reduction of the absorption of toxic products of intestinal microbial degradation, such as p-cresol;
- -
- Retarding effect on digesta transit: slower passage rate of digesta through the intestines and more efficient use of nutrients.
6. Conclusions
Author Contributions
Funding
Conflicts of Interest
References
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Zeolite | Representative Unit-Cell Formula | Void Volume, % | Channel Dimensions, Å | Thermal Stability (Relative) | CEC, meq/g * |
---|---|---|---|---|---|
Analcime | Na10(Al16Si32O96) ●16H2O | 18 | 2.6 | High | 4.54 |
Chabazite | (Na2Ca)6(Al12Si24O72) ●40H2O | 47 | 3.7 × 4.2 | High | 3.84 |
Clinoptilolite | (Na3K3)(Al6Si30O72) ●24H2O | 34 | 3.9 × 5.4 | High | 2.16 |
Erionite | (NaCa0.5K)9(Al9Si27O72) ●27H2O | 35 | 3.6 × 5.2 | High | 3.12 |
Faujasite | (Na58)(Al58Si134O384)●240H2O | 47 | 7.4 | High | 3.39 |
Ferrierite | (Na2Mg2)(Al6Si30O72) ●18H2O | 28 | 4.3 × 5.5 | High | 2.33 |
Heulandite | (Ca4)(Al8Si28O72) ●24H2O | 39 | 4.0 × 5.54.4 × 7.24.1 × 4.7 | Low | 2.91 |
Laumonitte | (Ca4)(Al8Si16O48) ●16H2O | 34 | 4.6 × 6.3 | Low | 4.25 |
Mordenite | (Na8)(Al8Si40O96) ●24H2O | 28 | 2.9 × 5.76.7 × 7.0 | High | 2.29 |
Phillipsite | (NaK)5(Al5Si11O32) ●20H2O | 31 | 4.2 × 4.42.8 × 4.83.3 | Medium | 3.31 |
Linde A | (Na12)(Al12Si12O48) ●27H2O | 47 | 4.2 | High | 5.48 |
Linde X | (Na86)(Al86Si106O384) ●264H2O | 50 | 7.4 | High | 4.73 |
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Cataldo, E.; Salvi, L.; Paoli, F.; Fucile, M.; Masciandaro, G.; Manzi, D.; Masini, C.M.; Mattii, G.B. Application of Zeolites in Agriculture and Other Potential Uses: A Review. Agronomy 2021, 11, 1547. https://doi.org/10.3390/agronomy11081547
Cataldo E, Salvi L, Paoli F, Fucile M, Masciandaro G, Manzi D, Masini CM, Mattii GB. Application of Zeolites in Agriculture and Other Potential Uses: A Review. Agronomy. 2021; 11(8):1547. https://doi.org/10.3390/agronomy11081547
Chicago/Turabian StyleCataldo, Eleonora, Linda Salvi, Francesca Paoli, Maddalena Fucile, Grazia Masciandaro, Davide Manzi, Cosimo Maria Masini, and Giovan Battista Mattii. 2021. "Application of Zeolites in Agriculture and Other Potential Uses: A Review" Agronomy 11, no. 8: 1547. https://doi.org/10.3390/agronomy11081547
APA StyleCataldo, E., Salvi, L., Paoli, F., Fucile, M., Masciandaro, G., Manzi, D., Masini, C. M., & Mattii, G. B. (2021). Application of Zeolites in Agriculture and Other Potential Uses: A Review. Agronomy, 11(8), 1547. https://doi.org/10.3390/agronomy11081547