Eco‐friendly three‐dimensional hydrogels for sustainable agricultural applications: Current and future scenarios

Modern world is searching for water efficient agriculture techniques as irrigation is becoming scarce. Limited water resources and more food demand are the two key challenges in agriculture. Hydrogels which can respond intelligently by pH, temperature, light, ionic strength, osmotic pressure, magnet...

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Bibliographic Details
Published in:Polymers for advanced technologies 2023-09, Vol.34 (9), p.3046-3062
Main Authors: Azeem, Muhammad Khalid, Islam, Atif, Khan, Rafi Ullah, Rasool, Atta, Qureshi, Muhammad Anees ur Rehman, Rizwan, Muhammad, Sher, Farooq, Rasheed, Tahir
Format: Article
Language:English
Subjects:
3D‐hydrogels
agricultural applications
Agriculture
Biocompatibility
biopolymeric blending
Blending effects
Capillarity
control release fertilizers
Crop yield
Electric fields
Fertilizers
Fillers
Germination
Hydrogels
Moisture content
nanofillers
Nitrates
Nutrients
Osmosis
Plant roots
Temperature dependence
Water resources
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Summary:Modern world is searching for water efficient agriculture techniques as irrigation is becoming scarce. Limited water resources and more food demand are the two key challenges in agriculture. Hydrogels which can respond intelligently by pH, temperature, light, ionic strength, osmotic pressure, magnetic or electric field changes are termed as intelligent or smart hydrogels which are analogous to conventional hydrogels in preparatory methods and features. Lag phase, constant release and decay phase are three steps involved in release of nutrients from polymeric hydrogels. In fact, hydrogels act as little reservoirs of water and dissolve nutrients that are released in controlled manner anchored by plant roots via capillary action. Hydrogels also sustain optimum amount of water in water stress conditions and reabsorb water in moist conditions which ultimately increases seedling, seed germination, plant growth and crop yield. Fertilizer and salt release are majorly dependent upon pH and temperature followed by diffusion‐controlled mechanism. Cross‐linkers, binders and fillers play pivotal role in determining properties, architecture and hydrogel pores. In comparison to potassium (K+) and phosphate (PO4−3) ions, nitrates (NO3−1) and ammonium (NH4+1) ions exhibited faster release rate. This review spotlights application prospects of three dimensional hydrogel in agriculture. Initially, properties of hydrogels, their classification, preparatory methods, effect of natural‐synthetic‐polymer blending and role of fillers are stated. Afterward, hydrogel functioning, significance, advantages, mechanism of fertilizer release and agriculture specific applications of hydrogels are comprehensively described. In conclusion, extraordinary biocompatible, cheaper, stable, biodegradable, durable, non‐toxic and re‐wettable characteristics of hydrogel systems motivated their utilization in agronomical applications.
ISSN:1042-7147
1099-1581
DOI:10.1002/pat.6122