Preparation and properties of multifunctional polyaspartic acid/waste paper fiber-based superabsorbent composites

Superabsorbent composites (SACs) are widely used for agricultural applications acts as a miniature soil moisture reservoir for plants. While these substrates have excellent water retention properties, they often suffer from production costs and a variety of environmental challenges. Herein, polyaspartic acid (PASP), waste paper fibers (WPF) and 2-acrylamido-2-methyl-1-propanesulfonic acid (AMPS) graft copolymerize acrylic acid (AA) to pre-pare a novel multifunctional PASP-g-P(AA-co-AMPS)/WPF SACs. The synthesis conditions use to prepare the PASP-g-P(AA-co-AMPS)/WPF SACs are optimized, including PASP content, mass ratio of AMPS and AA, initiator content and cross-linker content. In addition, the water retention, salt and acid resistance, reversible swelling and temperature sensitivity of SACs are also investigated and analyzed in detail. Due to the uniform distribution and the rich pore structure, it has a maximum equilibrium adsorption capacity of optimal SACs in distilled water, tap water and NaCl solution (0.9 wt%) are determined to be 731.0 g g(-1), 189.2 g g(-1) and 81.4 g g(-1), respectively. Thus, PASP-g-P(AA-co-AMPS)/WPF SACs exhibit excellent environmental tolerance and provide a promising strategy for sustainable agriculture and desertification control.

Automated summary

This study successfully synthesized a multifunctional superabsorbent composite (SACs) by grafting acrylic acid (AA) onto polyaspartic acid (PASP), waste paper fibers (WPF), and 2-acrylamido-2-methyl-1-propanesulfonic acid (AMPS). The optimized synthesis conditions resulted in SACs with improved water retention, salt and acid resistance, reversible swelling, and temperature sensitivity. The SACs exhibited a maximum equilibrium adsorption capacity in distilled water, tap water, and NaCl solution, showing great potential for sustainable agriculture and desertification control.