Recent Achievements in Polymer Bio-Based Flocculants for Water Treatment
Abstract
:1. Introduction
2. Flocculation Mechanism
2.1. Charge Neutralization
2.2. Polymer Bridging
3. Determination of Flocculation Efficiency and Mechanisms
4. Factors Affecting Flocculation
4.1. Effect of pH
4.2. Effect of Salt
4.3. Effect of Shear Rate
4.4. Effect of Other Factors
5. Bio-Based Polysaccharide Flocculants for Water Treatment
5.1. Starch and Its Derivatives
5.2. Chitosan and Its Derivatives
5.3. Cellulose and Its Derivatives
5.4. Other Examples of Natural Polymers Flocculants
6. A New Approach in Obtaining Flocculants
6.1. Bioflocculants Produced by Microorganisms
6.2. Nanoflocculants
6.3. Smart Flocculants—Stimuli Responsive Biopolymers
7. Conclusions
Author Contributions
Funding
Acknowledgments
Conflicts of Interest
References
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Bio-Based Flocculants | Applications | Reference |
---|---|---|
Starch: | ||
| Turbidity removal from suspension of kaolin, bentonite, and natural clay | [82,83] |
| Clarification of kaolin and hematite suspension | [84] |
| Kaolin suspensions clarification | [85] |
| Kaolin suspension clarification | [16] |
| Removal of metal ions | [86] |
| Removal of dye from its aqueous solution | [87] |
Chitosan: | ||
| Surface water treatment | [88] |
| Turbidity and TDS removal | [89] |
| Dyes removal from aqueous solutions | [17] |
| Color removal | [37] |
| Dyes removal | [90] |
| Dyes removal | [91] |
| Turbidity removal | [92] |
| Dye removal | [69] |
| Removal of fluoride, nitrate and phosphate from aqueous solution | [54] |
| ||
| Turbidity removal | [93] |
| Heavy metal removal | [94] |
| Water purification from zinc phosphate | [95] |
Cellulose: | ||
| Water decolorization | [79] |
| Clarification of kaolin and iron-ore suspension | [96] |
| Turbidity removal from drinking water | [97] |
| Municipal wastewater treatment; Turbidity removal | [98,99] |
| Kaolin suspension clarification | [18] |
| Flocculation in pulp slurries | [100] |
| Decolorization of colored effluents | [101] |
| Turbidity and COD removal | [102] |
| Anionic dyes solution remediation | [103] |
| Textile industry effluent treatment | [49] |
| Decolorization and turbidity removal | [104] |
| Treatment of water contaminated by oil spills (removal of organic and inorganic matter, adsorption of heavy metals) | [105] |
Alginate | ||
| Removal heavy metal ions and organic pollutants from wastewater | [106] |
| Coal fine suspension clarification | [107] |
| Heavy metal ions and humic acids removal | [108] |
| Water decolorization | [109] |
| ||
| Turbidity removal | [110] |
| Removal of pesticides | [111,112] |
Xanthan gum | ||
| Mine wastewater treatment for color removal, treatment of synthetic effluents and removal of Pb(II) ions from aqueous solution | [113,114] |
| Wastewater treatment | [115] |
Dextran | ||
| Removal of turbidity and pesticides | [116] |
| Removal dyes from wastewater | [117] |
Pectin | ||
| Removal of oil and Cr(VI) from wastewater | [118] |
| Heavy metal ions removal | [119] |
| Kaolin suspension treatment | [120] |
| Kaolin suspension treatment | [121] |
| Turbidity removal | [122] |
| Suspended solids removal | [123] |
Guar gum | ||
| Removal of COD, turbidity and biological contaminants from municipal wastewater | [124] |
| Bentonite aggregation | [125] |
Lignin and tannin | ||
| Removing of cationic dye | [50] |
| Turbidity removal | [126] |
| Turbidity removal | [127] |
| Heavy metal removal | [128] |
| Algal water treatment | [129] |
Microorganism | Applications | Reference |
---|---|---|
Bacillus cereus | Wastewater treatment for heavy metal removal | [173] |
Enterobacter sp. | Kaolin clay flocculation | [174] |
Klebsiella sp. | Water treatment; removal of amoeba cyst from water; sludge dewatering | [172,180,181] |
Mucor rouxii | Wastewater treatment | [182] |
Achromobacter sp. | Wastewater treatment | [183] |
Bacillus and Streptomyces sp. | Swine wastewater treatment | [184] |
Bacillus and Rhizobium radiobacter | Water treatment | [185] |
Basillus sp. | Treatment of wastewater | [186] |
Treatment of low temperature drinking water | [187] | |
Industrial wastewater treatment (COD removal and dye decolorization) | [188] | |
Penicillium sp. | Management of industrial wastewater | [188] |
Herbaspirillium spp. and Pseudomonas sp. | Industrial effluents and wastewater treatment (suspension particle and heavy metals removal) | [189] |
Rhodococcus sp. | Treatment of swine wastewater | [190] |
Serratia sp. | Treatment of wastewater | [191] |
Staphylococcus and Pseudomonas sp. | Treatment of industrial wastewater (COD, indigotin and dyeing wastewater) | [192] |
Proteus mirabilis | Wastewater treatment (waste sludge dewatering) | [193] |
Aspergillus flavus | Suspended solids removal | [194] |
Klebsiella variicola | Removal of turbidity and SS in drinking water | [195] |
Bacillus firmus | Water treatment (removal of metal ions such as Pb, Cu, Zn) | [196] |
Trichoderma sp. | Heavy metals ions removal | [197] |
Streptomyces platensis | Kaolin clay flocculation | [198] |
Oceanobacillus polygoni | Tannery wastewater treatment | [199] |
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Maćczak, P.; Kaczmarek, H.; Ziegler-Borowska, M. Recent Achievements in Polymer Bio-Based Flocculants for Water Treatment. Materials 2020, 13, 3951. https://doi.org/10.3390/ma13183951
Maćczak P, Kaczmarek H, Ziegler-Borowska M. Recent Achievements in Polymer Bio-Based Flocculants for Water Treatment. Materials. 2020; 13(18):3951. https://doi.org/10.3390/ma13183951
Chicago/Turabian StyleMaćczak, Piotr, Halina Kaczmarek, and Marta Ziegler-Borowska. 2020. "Recent Achievements in Polymer Bio-Based Flocculants for Water Treatment" Materials 13, no. 18: 3951. https://doi.org/10.3390/ma13183951
APA StyleMaćczak, P., Kaczmarek, H., & Ziegler-Borowska, M. (2020). Recent Achievements in Polymer Bio-Based Flocculants for Water Treatment. Materials, 13(18), 3951. https://doi.org/10.3390/ma13183951