2. Bogaard, T. A. & Greco, R. Landslide hydrology: from hydrology to pore pressure. Wiley Interdisciplinary Reviews: Water 3, 439-459 (2016).
3. Gelencsér, A. et al. The red mud accident in Ajka (Hungary): characterization and potential health effects of fugitive dust. Environmental Science & Technology 45, 1608-1615 (2011).
4. Parvej, S. et al. Fugitive Dust Suppression in Unpaved Roads: State of the Art Research Review. Sustainability 13, 2399 (2021).
5. Afrin, H. A review on different types soil stabilization techniques. International Journal of Transportation Engineering and Technology 3, 19-24 (2017).
6. Chen, C., Habert, G., Bouzidi, Y. & Jullien, A. Environmental impact of cement production: detail of the different processes and cement plant variability evaluation. Journal of Cleaner Production 18, 478-485 (2010).
7. Roy, A. Soil stabilization using rice husk ash and cement. International Journal of Civil Engineering Research 5, 49-54 (2014).
8. Ghadir, P. & Ranjbar, N. Clayey soil stabilization using geopolymer and Portland cement. Construction and Building Materials 188, 361-371 (2018).
9. Ahmed, E. M. Hydrogel: Preparation, characterization, and applications: A review. Journal of Advanced Research 6, 105-121 (2015).
10. Guo, Y. et al. Hydrogels and hydrogel-derived materials for energy and water sustainability. Chemical Reviews 120, 7642-7707 (2020).
11. Zhao, Z. et al. Biomimetic hydrogel composites for soil stabilization and contaminant mitigation. Environmental Science & Technology 50, 12401-12410 (2016)
12. Lo, C. Y. et al. Durable and ductile double-network material for dust control. Geoderma 361, 114090 (2020).
13. Hamdan, N., Zhao, Z., Mujica, M., Kavazanjian, E. & He, X. Hydrogel-assisted enzyme-induced carbonate mineral precipitation. Journal of Materials in Civil Engineering 28, 0401689 (2016).
14. Rizwan, M., Gilani, S. R., Durani, A. I. & Naseem, S. Materials diversity of hydrogel: Synthesis, polymerization process and soil conditioning properties in agricultural field. Journal of Advanced Research 33, 15-40 (2021).
15. Wen, K. et al. Mechanical behaviors of hydrogel-impregnated sand. Construction and Building Materials 207, 174-180 (2019).
16. Buenger, D., Topuz, F. & Groll, J. Hydrogels in sensing applications. Progress in Polymer Science 37, 1678-1719 (2012).
17. Subramani, R. et al. The influence of swelling on elastic properties of polyacrylamide hydrogels. Frontiers in Materials 7, 212 (2020).
18. Sun, X., Miao, L., Wang, H., Chen, R. & Wu, L. Bio-cementation for the mitigation of surface erosion in loess slopes based on simulation experiment. Journal of Soils and Sediments (2022).
19. Priemel, T., Degtyar, E., Dean, M. N. & Harrington, M. J. Rapid self-assembly of complex biomolecular architectures during mussel byssus biofabrication. Nature Communications 8, 1-12 (2017).
20. Holten-Andersen, N., Fantner, G. E., Hohlbauch, S., Waite, J. H. & Zok, F. W. Protective coatings on extensible biofibres. Nature Materials 6, 669-672 (2007).
21. Zhao, C., Ma, Z. & Zhu, X. X. Rational design of thermoresponsive polymers in aqueous solutions: A thermodynamics map. Progress in Polymer Science 90, 269-291 (2019).
22. Xu, Y. et al. Development of visible-light responsive and mechanically enhanced “smart” UCST interpenetrating network hydrogels. Soft Matter 14, 151-160 (2018).
23. Leung, C. S., Leung, S. S., Tirado-Rives, J. & Jorgensen, W. L. Methyl effects on protein-ligand binding. Journal of Medicinal Chemistry 55, 4489-4500 (2012).
24. Zhang, J. & Peppas, N. A. Molecular interactions in poly (methacrylic acid)/poly (N‐isopropyl acrylamide) interpenetrating polymer networks. Journal of Applied Polymer Science 82, 1077-1082 (2001).
25. Mahinroosta, M., Farsangi, Z. J., Allahverdi, A. & Shakoori, Z. Hydrogels as intelligent materials: A brief review of synthesis, properties and applications. Materials Today Chemistry 8, 42-55 (2018).
26. Zhang, Y., Li, Y. and Liu, W. Dipole–dipole and H‐bonding interactions significantly enhance the multifaceted mechanical properties of thermoresponsive shape memory hydrogels. Advanced Functional Materials 25, 471-480 (2015).
27. Kim, J., Zhang, G., Shi, M. & Suo, Z. Fracture, fatigue, and friction of polymers in which entanglements greatly outnumber cross-links. Science 374, 212-216 (2021).
28. Wang, Y. et al. A composite hydrogel with high mechanical strength, fluorescence, and degradable behavior for bone tissue engineering. Polymers 11, 1112 (2019).
29. Speight, J. G. Lange's Handbook of Chemistry (McGraw Hill, New York, 2005).
30. Bolan, N. S., Naidu, R., Syers, J. K. & Tillman, R. W. Surface Charge and Solute Interactions in Soils. Advances in Agronomy 67, 87-140 (1999).
31. Tokarev, I. & Minko, S. Stimuli‐responsive porous hydrogels at interfaces for molecular filtration, separation, controlled release, and gating in capsules and membranes. Advanced Materials 22, 3446-3462 (2010).
32. Zhao, Z., Wang, C., Yan, H., & Liu, Y. Soft robotics programmed with double crosslinking DNA hydrogels. Advanced Functional Materials 29, 1905911 (2019).
33. Schuch, A. P. & Menck, C. F. M. The genotoxic effects of DNA lesions induced by artificial UV-radiation and sunlight. Journal of Photochemistry and Photobiology B: Biology 99, 111-116 (2010).
34. Hamza, M. A. & Anderson, W. K. Soil compaction in cropping systems: A review of the nature, causes and possible solutions. Soil and Tillage Research 82, 121-145 (2005).
35. Gregory, J. H., Dukes, M. D., Jones, P. H. & Miller, G. L. Effect of urban soil compaction on infiltration rate. Journal of Soil and Water Conservation 61, 117-124 (2006).