1、Hybrid super absorbent resin based on waste slag modified zeolite: A
The examinations and characterizations showed that the hybrid SAR modified by zeolite prepared from mine slag had excellent water release under some pressure and resistance to salinity.
2、Journal of Applied Polymer Science
Corn stover (CS), humic acid (HA), acrylic acid (AA), and acrylamide (AM) were used as raw materials to produce CS–HA-based superabsorbent resin (p-CS-HA-PAA) by plasma modification, and the optimum modification conditions were obtained.
3、A comprehensive assessment of superabsorbent resin
Superabsorbent polymers: A state-of-art review on their classification, synthesis, physicochemical properties, and applications Superabsorbent polymers (SAP) and modified natural polymer hydrogels are widely and increasingly used in agriculture, health care textiles, effluent treatm...
Novel superabsorbent polymer composites based on α
In this article, a new SAP composite was synthesized by using AA, AM, α-cellulose, and modified zeolite (MZE). The prepared SAP composites were analysed by FTIR spectroscopy, XRD, SEM and TGA. Then, their water absorbency and water retention capacity results were evaluated.
A comprehensive assessment of superabsorbent resin produced using
To enhance the utilization of biomass waste quinoa husk (QH) and solid waste CFA and reduce the preparation cost of superabsorbent resin (SAR), a low-cost, biodegradable modified quinoa husk-g-poly (acrylic aci …
Research Advances in Superabsorbent Polymers
This paper reviews the synthesis and modification methods of different superabsorbent polymers, summarizes the processing methods for different forms of superabsorbent polymers, and organizes the applications and research progress of superabsorbent polymers in industrial, agricultural, and biomedical industries.
Hybrid super absorbent resin based on waste slag modified
The hybrid super absorbent resin (SAR), Poly (acrylicacid-co-acrylamide-co-2-acrylamido-2-methyl-1-propane sulfonic acid) based on zeolite synthesized from solid waste slag (P (AA-co-AM-co-AMPS)/zeolite) was synthesized.
A comprehensive assessment of superabsorbent resin produced using
In this work, modified quinoa husk (MQH) using, acrylic acid and CFA were utilized to synthesize a low-cost, degradable MQH -g-PAA/CFA SAR by aqueous solution polymerization. The synthesis conditions were optimized and the swelling kinetics and water retention kinetics of SAR were discussed.
Preparation and properties of modified fly ash
Preparation and properties of modified fly ash-based superabsorbent resin [J]. New Chemical Materials, 2025, 53 (2): 241-246 https://doi.org/10.19817/j.cnki.issn1006-3536.2025.02.024.
Hybrid Super Absorbent Resin Based on Waste Slag
The hybrid super absorbent resin (SAR), Poly (acrylicacid-co-acrylamide-co-2-acrylamido-2-methyl-1-propane sulfonic acid) based on zeolite synthesized from solid waste slag (P (AA-co-AM-co-AMPS)/zeolite) was synthesized.
In modern industry and daily life, the demands for material performance are increasingly stringent, particularly for applications in extreme environments. Superabsorbent resins, as a critical class of functional materials, have garnered significant attention due to their exceptional water absorption and retention properties. Modified hybrid superabsorbent resin (MAP), which offers enhanced comprehensive performance, holds vast potential for research and application. This paper aims to explore the preparation methods, performance characteristics, and practical application potential of modified hybrid superabsorbent resin (MAP).
1. Overview of Modified Hybrid Superabsorbent Resin (MAP)
Modified hybrid superabsorbent resin (MAP) is a novel material derived from conventional superabsorbent resins through specific chemical or physical modifications. By integrating the fundamental properties of superabsorbent resins with unique functionalities of modifiers, MAP maintains its superior water absorption capacity while improving stability, durability, and performance under specific environmental conditions.
2. Preparation Methods
The synthesis of MAP involves diverse approaches, categorized based on raw materials and modifiers:
- Blending Method: Physically or chemically combining superabsorbent resins with other polymers or inorganic fillers to create composites.
- Grafting Method: Chemically grafting monomers or prepolymers onto the surface or interior of superabsorbent resins to achieve modification.
- Crosslinking Method: Forming three-dimensional networks via chemical reactions to enhance mechanical strength and stability.
- Nanotechnology Method: Incorporating nanomaterials (e.g., nano-oxides, nano-clays) to improve performance.
- Surface Modification Method: Altering surface properties through physical or chemical treatments (e.g., introducing hydrophilic groups or modifying roughness) to enhance water affinity.
3. Performance Characteristics
MAP exhibits the following key advantages:
- High Water Absorption and Retention: Capable of absorbing large volumes of water and slowly releasing it under specific conditions to maintain humidity.
- Excellent Stability: Retains performance under harsh conditions (e.g., high temperatures, pressures) without degradation or deformation.
- Versatile Environmental Adaptability: Maintains functionality across varying pH levels, ionic strengths, and other environmental factors.
- Eco-Friendly Degradability: Some MAP variants are biodegradable, reducing environmental impact.
4. Application Fields
Due to its unique properties, MAP is widely utilized in diverse sectors:
- Agriculture: Soil moisture regulation and irrigation to optimize plant growth.
- Construction: Roof waterproofing and wall humidity control to extend building lifespan.
- Textiles: Enhancing fabric softness, comfort, and reducing washing frequency.
- Pharmaceuticals: Drug delivery systems to improve efficacy and minimize side effects.
- Consumer Goods: Humidity control in households (e.g., bathrooms, kitchens) for improved living quality.
5. Future Prospects
Advancements in technology will further drive MAP research and application. Key directions include:
- Performance Optimization: Refining preparation techniques to enhance stability, durability, and environmental adaptability.
- Multifunctional Development: Creating MAP products with diverse functions for broader applications.
- Green Manufacturing: Exploring eco-friendly production methods to minimize environmental impact.
- Smart Applications: Integrating sensor technologies for real-time humidity monitoring and control.
modified hybrid superabsorbent resin (MAP) is a promising material with versatile preparation methods,优异的性能(excellent performance),and wide-ranging applications. With ongoing research and technological progress, MAP is poised to play a pivotal role in enhancing convenience and comfort in numerous fields.
