Functional Hydrogels for Agricultural Application

Abstract: Ten different hydrogels were prepared and analyzed from the point of view of their use in soil. FT-IR spectra, morphology, swelling ability, and rheological properties were determined for their characterization and appraisal of their stability. The aim was to characterize prepared materials containing different amounts of NPK as mineral fertilizer, lignohumate as a source of organic carbon, and its combination. This study of stability was focused on utility properties in their application in soil—repeated dryi… Show more

“…Interestingly, both CMH hydrogels exhibited a surprising surge in water absorption (within 10–20 min) during the second cycle, surpassing their initial values of cycle 1. This phenomenon, attributed to potential structural changes during the drying process, underlines the dynamic nature of hydrogels and their ability to adapt to repeated wetting and drying cycles [ 48 , 58 ]. Additionally, chitosan content within CMHs seems to play a crucial role in WRV, with optimal water retention observed at 35% chitosan in CMH65.…”

Assessment of energy cane bagasse-derived cellulosic microfiber hydrogels on the growth of potted chili peppers

“…Interestingly, both CMH hydrogels exhibited a surprising surge in water absorption (within 10–20 min) during the second cycle, surpassing their initial values of cycle 1. This phenomenon, attributed to potential structural changes during the drying process, underlines the dynamic nature of hydrogels and their ability to adapt to repeated wetting and drying cycles [ 48 , 58 ]. Additionally, chitosan content within CMHs seems to play a crucial role in WRV, with optimal water retention observed at 35% chitosan in CMH65.…”

Assessment of energy cane bagasse-derived cellulosic microfiber hydrogels on the growth of potted chili peppers

“…In addition, Martina's group employed intelligent superabsorbent polymeric hydrogels, utilizing them as both a water reservoir and a supplier of mineral and organic nutrients with the aim of enhancing soil quality. In this case, the incorporation of NPK fertilizer reinforced the flexibility of the hydrogels, whereas the inclusion of lignohumate induced a shift in their rheological properties towards a more liquid-like behavior [11]. In light of the growing interest and attention toward hydrogel-based smart soils and relevant sustainable devices for tackling agricultural and environmental challenges, we recommend considering the following perspectives of smart hydrogels: (i) enhancing moisture retention and irrigation efficiency, (ii) implementing controlled nutrient release mechanisms, (iii) integrating soil health monitoring and environmental protection, (iv) ensuring compatibility with soil microorganisms, and (v) exploring additional avenues [12].…”

Editorial for Special Issue: Advances in Smart and Tough Hydrogels

“…In 2023, a research group highlighted the significance of biopolymer-based hydrogels in agriculture and their water-holding capabilities, emphasizing their dual role as soil conditioners and slow-release mechanisms for fertilizers in challenging conditions [ 155 ] (as shown in Figure 12 b,c). They discussed the use of hydrophilic hydrogels applied during planting or seed coating, primarily serving as carriers for nutrients and enhancers of soil quality [ 156 , 157 ]. Key considerations when selecting a hydrogel for soil enhancement include superabsorbent properties, biodegradability, and chemical crosslinking.…”

A Comprehensive Review of Radiation-Induced Hydrogels: Synthesis, Properties, and Multidimensional Applications