The Application of Modified Natural Polymers in Toxicant Dye Compounds Wastewater: A Review
Abstract
:1. Introduction
2. Characteristics of Dyes
3. Application of Polymers in Wastewater Treatment
4. Graft Polymer (Coagulant/Flocculant)
4.1. Factors Affecting the Efficiency of Polymer Coagulants
4.1.1. Type of Coagulant
4.1.2. Coagulant Concentrations and Mixing Conditions
4.1.3. Functional Groups
4.1.4. Molecular Weight (MW) of the Flocculant/Coagulant Aid
4.1.5. Type of Charge Density
5. Removal of Dyes by Using Modified Natural Polymers
6. Conclusions
Author Contributions
Funding
Acknowledgments
Conflicts of Interest
References
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Process | Advantages | Disadvantages | References |
---|---|---|---|
Physical Process | |||
Ion exchange | Good surface area, effective sorbent | Not effective for all dyes, derived from petroleum-based materials, sensitive to particle charge | [2] |
Adsorption | Effective for dye removal | Eco-friendly disposal of spent adsorbents, requires pretreatment, and costly maintenance | [3] |
Membrane filtration | Able to remove all types of dyes | Requires proper pretreatment for SS removal, membrane fouling, expensive | [4] |
Irradiation | Effective in lab settings | Requires large amounts of O2 | [5] |
Electrokinetic coagulation | Reasonable cost | High sludge problem | [6] |
Chemical process | |||
Cucurbituril | Good sorption capacity for different types of dyes | Expensive process | [7] |
Oxidation | Simple application | H2O2 needs to be activated | [8] |
Chemical coagulation-flocculation | Can remove dye molecules from dyebath effluent | High sludge production | [9] |
Ozonation | Efficient for colour removal | Aldehyde by-product | [10] |
Fenton’s reagent | able to treat soluble and insoluble colour pigments | Results in large amounts of precipitate | [11] |
Biological process | |||
Aerobic | Economically attractive and eco-friendly | Slow process | [12] |
Anaerobic | Decolourized azo and water-soluble dyes | Produces methane and hydrogen sulphide | [13] |
Decolourization by mixed cultures | Able to remove colour in 30 h | Lower efficacy, due to aerobic conditions | [14] |
Decolourization by white-rot fungus | Degrades dyes using enzymes | Unpredictable enzyme production | [15] |
Class | Substrates | Method of Application | Chemical Types |
---|---|---|---|
Acid | Nylon, wool, silk, paper, inks, and leather | Usually from neutral to acidic dyebaths | Azo (including premetallized), anthraquinone, triphenylmethane, azine, xanthene, nitro, and nitroso |
Azoic components and compositions | Cotton, rayon, cellulose acetate, and polyester | Fibre impregnated with coupling component and treated with a solution of stabilized diazonium salt | Azo |
Base | Paper, polyacrylonitrile, modified nylon, polyester, and inks | Applied from acidic dyebaths | Cyanine, hemicyanine, diazahemicyanine, diphenylmethane, triarylmethane, azo, azine, xanthene, acridine, oxazine, and anthraquinone |
Direct | Cotton, rayon, paper, leather, and nylon | Applied from neutral or slightly alkaline baths, containing additional electrolytes | Azo, phthalocyanine, stilbene, and oxazine |
Disperse | Polyester, polyamide, acetate, acrylic, and plastics | Fine aqueous dispersions often applied by using high-temperature/pressure, or lower-temperature carrier methods; dye may be padded on cloth and baked on, or thermofixed | Azo, anthraquinone, styryl, nitro, and benzodifuranone |
Mordant | Wool, leather, and anodized aluminium | Applied in conjunction with Cr salts | Azo and anthraquinone |
Oxidation bases | Hair, fur, and cotton aromatic | Amines and phenols oxidized on the substrate | Aniline black and indeterminate structures |
Reactive | Cotton, wool, silk, and nylon | Reactive site on dye reacts with functional group on fibre, to bind dye covalently under influence of heat and pH (alkaline) | Azo, anthraquinone, phthalocyanine, formazan, oxazine, and basic |
Solvent | Plastics, gasoline, varnishes, lacquers, stains, inks, fats, oils, and waxes | Dissolution in the substrate | Azo, triphenylmethane, anthraquinone, and phthalocyanine |
Sulphur | Cotton and rayon | Aromatic substrate vatted with sodium sulphide and reoxidized to insoluble sulphur-containing products on fibre | Indeterminate structures |
Vat | Cotton, rayon, and wool | Water-insoluble dyes, solubilised by reducing them with sodium hydrogen sulphite, then exhausted on fibre and reoxidized | Anthraquinone (including polycyclic quinones) and indigoids |
Heavy Metals | Toxicities |
---|---|
Arsenic (As) | Skin manifestations, visceral cancers, vascular disease |
Cadmium (Cd) | Kidney damage, renal disorder, human carcinogen |
Chromium (Cr) | Headache, diarrhea, nausea, vomiting, carcinogenic |
Copper (Cu) | Liver damage, Wilson’s disease, insomnia |
Nickel (Ni) | Dermatitis, nausea, chronic asthma, coughing, human carcinogen |
Zinc (Zn) | Depression, lethargy, neurological signs, and increased thirst |
Lead (Pb) | Damage to the fetal brain, kidney diseases, as well as circulatory system and nervous system diseases |
Mercury (Hg) | Rheumatoid arthritis, kidney diseases, as well as circulatory system, and nervous system diseases |
Parameter | Unit | Malaysia [39] | Jordan [40] | Bangladesh [41] | Nigeria [42] | Singapore [43] | US EPA [44] |
---|---|---|---|---|---|---|---|
Temperature | °C | 40 | Summer: 40, Winter: 45 | Summer: 40 Winter: 45 | <40 | 45 | 40 |
pH Value | - | 5.5–9.0 | 6.0–9.0 | 6.0–9.0 | 6.0–9.0 | 6.0–9.0 | 6.0–8.5 |
BOD | mg/L | 50 | 50 | 50 | 50 | 50 | 40 |
SS | mg/L | 100 | 150 | 150 | NL | 50 | TSS: 50 |
Hg | mg/L | 0.05 | 0.01 | 0.01 | NL | 0.05 | 0.005 |
Cd | mg/L | 0.02 | 0.05 | 0.05 | <1 | 0.1 | 0.01 |
Cr | mg/L | 0.05 | 0.5 | 0.5 | <1 | 1 | 0.1 |
Cr3 | mg/L | 0.1 | NL | NL | <1 | 1 | 0.5 |
As | mg/L | 0.1 | 0.2 | 0.2 | NL | 0.1 | 0.2 |
Cyanide (Cn) | mg/L | 0.1 | 0.1 | 0.1 | NL | 0.1 | 0.2 |
Lead (Pb) | mg/L | 0.5 | 0.1 | 0.1 | <1 | 0.1 | 0.1 |
Copper (Cu) | mg/L | 1.0 | 0.5 | 0.5 | NL | 0.1 | 3.0 |
Manganese (Mn) | mg/L | 1.0 | 5 | 5 | NL | 5 | NL |
Nickel (Ni) | mg/L | 1.0 | 1 | 1 | <1 | 1 | 3.0 |
Sn | mg/L | 1.0 | NL | NL | NL | 10 | NL |
Zinc (Zn) | mg/L | 2.0 | 5 | 5 | NL | 1 | 2.0 |
Boron (B) | mg/L | 4.0 | 2 | 2 | NL | 5 | NL |
Iron (Fe) | mg/L | 5.0 | 2 | 2 | NL | 10 | 3.0 |
(xix) Silver (Ag) | mg/L | 1.0 | NL | NL | NL | 0.1 | NL |
(xx) Aluminium (Al) | mg/L | 15 | NL | NL | NL | NL | NL |
(xxi) Selenium (Se) | mg/L | 0.5 | 0.05 | 0.05 | NL | 0.5 | 0.05 |
(xxii) Barium (Ba) | mg/L | 2.0 | NL | NL | NL | 2 | NL |
(xxiii) Fluoride (F) | mg/L | 5.0 | 7 | 7 | NL | NL | 2.0 |
(xxiv) Formaldehyde | mg/L | 2.0 | NL | NL | NL | NL | NL |
(xxv) Phenol | mg/L | 1.0 | 1 | 1 | NL | 0.2 | 1.0 |
(xxvi) Free Chloride | mg/L | 2.0 | 600 | 600 | 600 | NL | 1500 |
(xxvii) Sulphide | mg/L | 0.50 | 1 | 1 | NL | 0.2 | 2.0 |
(xxviii) Oil and Grease | mg/L | 10 | 10 | 10 | NL | 10 | 10 |
(xxix) Ammoniacal Nitrogen | mg/L | 20 | 50 | 50 | NL | NL | 50 |
(xxx) Colour | ADMI * | 200 | NL | NL | NL | 7 Lovibond Units | 456 nm: 7 m−1,525 nm: 5 m−1, 620 nm: 3 m−1 |
(xxxi) COD: (a) Pulp and paper industry
| mg/L mg/L mg/L | 200 350 250 300 | 200 NL NL NL | 200 NL NL NL | 150 NL NL NL | 100 NL NL NL | 250 NL NL NL |
(b) Textile industry | mg/L | 250 | NL | NL | NL | NL | NL |
(c) Fermentation and distillery industry | mg/L | 400 | NL | NL | NL | NL | NL |
(d) Other industries | mg/L | 200 | NL | NL | NL | NL | NL |
Natural Polymer | Types Of Wastewater | Treatment Process | Condition | Type Of Dye | Colour Removal | References |
---|---|---|---|---|---|---|
Pectin | Textile wastewater | Coagulation and flocculation | pH 5, 427.4 mg/l MgCl2 and 21.9 mg/l pectin | -NA- | 54.20% | [57] |
Synthetic dye | Adsorption | pectin dose 20 mg; pH 8 20 mg/l of Methylene blue | Methylene blue dye | 45.00% | [58] | |
Synthetic dye | Adsorption | pH 2, 247.4 mg/l dose; 34.32 mg/l dye concentration; 540-min time | Crystal Ponceau 6 R dye | 99.20% | [59] | |
Synthetic dye | Adsorption | no pH adjustment; 20 mg of beads was added to 50 mL of the dye solution | Methylene blue dye | 1550.3 mg/g for Pectin bead and 2307.9 mg/g for pectin/cellulose microfiber bead | [60] | |
Chitosan | Synthetic dye | Coagulation & flocculation | pH 4.0, coagulant dose of 25 mg/l, flocculation time of 60 min and temperature of 340 K | Congo Red (CR) dye removal- | 94.50% | [61] |
Synthetic dye | Adsorption | chitosan beads, 1-butyl-3-methylimidazolium acetate and 1-butyl-3-methylimidazolium (pH 4.0, dose of 0.008 g, and agitation time of 20 min) | Malachite Green (MG) dye | 8.07 mg g−1 and 0.24 mg g−1 | [65] | |
Palm oil mill effluent | Coagulation and flocculation | 3 g/L alum + 0.4 g/L chitosan pH 4.51, 250-rpm rapid mixing speed for 3 min, 30-rpm slow mixing speed for 30 min, and 60 min settling time. | - | 95.24% | [60] | |
Cellulose/Polyaniline (Ce/Pn) Nanocomposite | Synthetic dye | Adsorption process | Remazol dye effluent | 95.90%, 91.90%, 92.70%, and 95.70% of RBBR, RO, RV, and RBK, respectively. | [61] | |
Alginate | Synthetic dyes | Activated carbon | Methylene blue and Methyl orange dyes | 50.00% Methylene blue in 10 min and Methyl orange in 17 min | [62] | |
Acanthocerous Tetragonus (Cactus) | Synthetic dyes | Coagulation | pH 6 at dose of 5 mg/L pH 4 at dose of 6 mg/L | Congo red dye Direct blue dye | 96.00% 90.00% | [62] |
Moringa Oleifera Seeds (Mos) | Synthetic dyes | Adsorption | pH 5 at MOS dose of 0.5 g and 150 mg/L concentration of dye | Indigo carmine (reactive dye) | 31.25 mg g−1 | [63] |
GrewiaVenusta Peel (Gvp) | Synthetic dye | Adsorption | pH 2 at 0.5 g of GVP and 150 mg/L dye concentration | Methyl orange dye | 85.00% 188.68 mg g−1 | [63] |
Okra Mucilage (Abelmoschus Esculentus) | Textile wastewater (during washing and finishing processes) | Coagulation and flocculation | pH 6 at 3.20-mg/L dose of Okra, and 88.0 mg/L of Fe3+ | - | 93.57% 5.78 mg g−1 | [64] |
Tannin | Synthetic dye | Coagulation and flocculation | pH 2.9 (Bentonite+ anionic flocculant) pH 2.2 (Bentonite+ anionic PAM) pH 3.4 (Bentonite+ cationic PAM) pH 2.8 (Bentonite + cationic flocculant) | Methylene blue Crystal violet Duasyn direct dye Acid black 2 | >90.00% 89.00% 99.00% 83.00% | [66] |
Manufacturing wastewater treatment | Coagulation and flocculation | - | - | 99.00% | [66] | |
Gums C. Javahikai Seed Gum (Cj) | Synthetic dyes | Coagulation and flocculation | Direct dyes | >70.00% | [67] |
Monomers | Classes | Molecular Structure | Removal Percentage | References |
---|---|---|---|---|
poly(2-methacryloyloxyethyl) trimethylammonium chloride (PDMC) | Cationic | 90% Acid Green 25 at pH 4 98% Basic Bright Yellow at pH 11 | [69] | |
Diallyldimethyl ammonium Chloride | Cationic | >98.54% of methylene blue and 83.07% of anionic dye orange II pH = 4 and 11 | [68] | |
Diethanolamine | Cationic | 99.6% of Congo red, 99.8% of methyl blue, 97.5% of sunset yellow, and 81.2% of neutral red | [71] | |
Polyethylenimine | Cationic | Adsorption rate of 264.5 mg/g for amino black dye at pH 3 | [70] | |
Acrylamide | Non-ionic | >99% of methylene blue at pH 10 | [72] | |
Acrylic acid | Anionic | 99.5% of Congo red and 98.7% of methylthionine chloride | [69] | |
Poly(glycidyl methacrylate) | Anionic | 98.5% using 200 mg/L of methyl orange and methylene blue dyes | [73] | |
Triochloroaceticac | Anionic | Nearly 99% Rhodamine B, malachite green, and anionic dye orange were at concentration 222.6, 190.6, and 40 mg g−1, respectively, at pH < 3 | [74] |
Polymers | Functional Groups |
---|---|
Chitosan | Chitosan was identified by the presence of OH groups, with NH band overlapping around 3300 cm−1; with additional NH stretching vibrations at 1649 cm−1 and 1578 cm−1, and C-O bonds appearing at 1419 cm−1 and 1378 cm−1, due to the presence of remaining acetylated moieties of chitin [103]. |
Tannin | Tannin can be recognized by the vibration of phenolic hydroxyl group, identified by peaks at 3200–3700 and 1325 cm−1. The C-O aromatic ring and the C-C stretching vibration were observed at 1204 and 1536 cm−1, respectively. The absorption peak between 1000 and 1150 cm−1 was associated with ethers (C−O−C) [103]. |
Moringa olefera | Moringa oleifera spectrum showed the absorption of OH stretching at 3400 cm−1; symmetric stretching of C-H at 2925 cm−1; carboxylic group (COO−) stretching bands at 1610 cm−1 and 1451 cm−1, and carbonyl group (C-O) stretching at d 1070 cm−1) [104]. |
Zinc oxide nanoparticles | The absorption of a large number of hydroxyl groups is indicated by the broad peak between 3500 and3100 cm−1; and Zn-O bond stretching is indicated by the lower absorption peak < 600 cm−1 [105]. |
Polyacrylamide | Polyacrylamide spectrum demonstrates broad absorption bands at 3421 and 3192 cm−1, indicating N-H stretching vibrations. The absorbance peaks at 1655 cm−1 correspond to the asymmetric C = O stretching vibrations [106]. |
Graphene oxide | Common absorption bands, observed at 3387 cm−1, are ascribed to −OH stretching vibrations. The C = O groups (−COOH), the C = C stretching, the C-O-C stretching, and the C-O (C-OH) stretching peak can be seen at 1730, 1621, 1224, and 1049 cm−1, respectively [106]. |
Sodium alginate | Hydroxyl absorption peak was recorded at 3421 cm−1; asymmetric and symmetric stretching vibrations of carboxylic groups were observed at the peaks near 1621 cm−1 and 1395 cm−1 [106]. |
Carboxymethyl cellulose | Carboxymethyl cellulose (CMC) can be identified by the wide spectra associated with ether bonds at absorption peaks between 1000 and 1100 cm−1. The absorption band at 1588 cm−1 was attributed to the scissoring mode of the carboxylic groups (COO-) [73]. |
Pectin | Pectin absorption band were indicated by five bands at 1019, 1052, 1076, 1104, and 1149 cm−1. Meanwhile, other bands at 1350–1750 were associated with carboxylic groups and C = O stretching in the protonated carboxyl group. In addition, two bands, representing symmetric and asymmetric stretching modes in carboxylic group at 1600–1650 cm−1 and 1400–1450 cm−1, respectively. In addition, the ether and the C-C bond included in the molecule of pectin were indicated by the absorption bands between 1100 and 1200 cm−1 [107]. |
Locust bean gum | The previous spectrum showed a broad peak at 3311 cm−1, which is assigned to the O-H group. The presence of sharp peaks at 1004 cm−1 was attributed to C-O-H vibrations [108]. |
Graft Polymer (Modified) | Additional Compound | Types of Wastewater | Treatment Process | Response | Percentage Removal (%) | References |
---|---|---|---|---|---|---|
Amine Modified Tannin Gel Mw: Na | Aqueous ammonia | Synthetic wastewater, using Brilliant green dye | Adsorption | Colour removal | 94.05 | [47] |
Tannin Extracts (Acacia Mearnsii De Wild And Schinopsis Balansae) Mw: Na | Clarotan with diethanolamine and formaldehyde | Guadiana River, in Badajoz (south-western Spain) | Coagulation and flocculation | Turbidity removal | >90.00 | [128] |
Chitosan—TiO2 Nanoparticles | Titanium dioxide nano particles | Simulated textile wastewater | Coagulation and flocculation | Removal of Cd, Cu, and Pb | <97.00 | [129] |
Chitosan Modified With CHPATC | Cationic moiety N-3-chloro-2-hydroxypropyl trimethyl ammonium chloride (CHPTAC) in presence of sodium hydroxide | Simulated laundry wastewater | Coagulation and flocculation | Colour Turbidity | 76.20 90.94 | [130] |
Cationic Amylopectin Mw: 6.89 × 104 g/Mol Cationic Amylose Mw: 2.64 × 106 g/Mol Cationic Chitosan Mw: 1.2 × 105 g/Mol Cationic Glycogen 6.81 × 106 g/Mol Cationic Guar Gum Mw: 6.6 × 105 g/Mol Cationic Starch Mw: 4.32 × 105 g/Mol Cationic Tamarind Kernel Polysaccharide Mw: 6.12 × 106 g/Mol | - | Synthetic reactive black dye | Adsorption | Colour removal | 78.00 50.00 >80.00 96.20 70.00 65.00 82.00 | [67] |
Cassia Javahikai Seed Gum-Grafted Polyacrylamide (Cjg), Mw: Na | Polyacrylamide PAM | Textile wastewater effluent | Coagulation and flocculation | Colour removal Total suspended solid | 35.00 80.00 | [67] |
Tannin-Based Hydrogel Mw: Na | Grafted Copolymer of Allyl Glycidyl Ether with Acrylamide | Synthetic heavy metal | Adsorption | Lead (Pb) removal | 99.00 at (0.5 mmol/L) | [131] |
Carboxymethyl Chitosan Grafted Polyacrylamide (Cmc-G-Pam) Mw: Na | Grafted polyacrylamide | Synthetic dye Methyl orange (anionic dye) Basic right yellow (cationic dye) | Coagulation and flocculation | Colour removal | 93.00 | [132] |
Lignosulfonate–Acrylamide–Chitosan | Grafted with lignosulfonate and acrylamide | Acid blue 115 Reactive black 5 Methyl orange | Flocculation | Colour removal | >95.0 >95.0 >50.0 | [133] |
Hydroxypropyl Methyl Cellulose, Grafted With Polyacrylamide (Hpmc-G-Pam) Mw: Na | Grafted polyacrylamide | Raw mine wastewater | Coagulation and flocculation | Turbidity | 95.00 | [83] |
Hydrolysed Polyacrylamide-Grafted Carboxymethyl starch (Hyd. Cms-G-Pam) Mw: Na | Grafted Carboxymethyl starch | Textile wastewater | Coagulation and flocculation | Colour removal | 88.18 | [28] |
Polyacrylamide-Grafted Sodium Alginate Mw:Na | Grafted sodium alginate | Synthetic dye | Adsorption | Colour removal | 99.00 | [134] |
Chitosan-Acrylamide-Fulvic Acid (Camfa) | Grafted with acrylamide and fulvic acid | Methylene Blue Acid blue 113, reactive black 5 and methyl orange | Adsorption | Colour removal | 99.00 97.00 91.60 | [135] |
Polyethylenimine-Grafted Cellulose Mw: Na | Grafted with Cellulose | Silk printing and dyeing wastewater | Flocculation | Total suspended solid (TSS) COD reductionTurbidity Total suspended solid (TSS) COD reduction Turbidity | 38.20 73.40 95.70 87.40 96.20 79.90 | [136] |
Bamboo Pulp Cellulose Grafting Polyacrylamide (Bpc-G-Pam) | Grafted with polyacrylamide | Cationic and disperse dye | Flocculation | Colour removal | 87.20 97.00 | [137] |
Carboxymethylcellulose-G- Poly[(2-Methacryloyloxyethyl) Trimethyl Ammonium Chloride] (Cmc-G-Pdmc) | graft poly[(2-methacryloyloxyethyl) trimethyl ammonium chloride] | Machining wastewater Acid green 25 | Coagulation and flocculation | Colour removal | 93.50 | [69] |
Pafc-Starch-G-P(Am-Dmdaac) | graft copolymer with acrylamide and dimethyl diallyl ammonium chloride | Brilliant blue KN-R Yellow M-3RE Dark blue M-2GE Green KE-4B | Coagulation and flocculation | Colour removal | 97.30 89.70 83.00 85.00 | [138] |
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Ishak, S.A.; Murshed, M.F.; Md Akil, H.; Ismail, N.; Md Rasib, S.Z.; Al-Gheethi, A.A.S. The Application of Modified Natural Polymers in Toxicant Dye Compounds Wastewater: A Review. Water 2020, 12, 2032. https://doi.org/10.3390/w12072032
Ishak SA, Murshed MF, Md Akil H, Ismail N, Md Rasib SZ, Al-Gheethi AAS. The Application of Modified Natural Polymers in Toxicant Dye Compounds Wastewater: A Review. Water. 2020; 12(7):2032. https://doi.org/10.3390/w12072032
Chicago/Turabian StyleIshak, Siti Aisyah, Mohamad Fared Murshed, Hazizan Md Akil, Norli Ismail, Siti Zalifah Md Rasib, and Adel Ali Saeed Al-Gheethi. 2020. "The Application of Modified Natural Polymers in Toxicant Dye Compounds Wastewater: A Review" Water 12, no. 7: 2032. https://doi.org/10.3390/w12072032
APA StyleIshak, S. A., Murshed, M. F., Md Akil, H., Ismail, N., Md Rasib, S. Z., & Al-Gheethi, A. A. S. (2020). The Application of Modified Natural Polymers in Toxicant Dye Compounds Wastewater: A Review. Water, 12(7), 2032. https://doi.org/10.3390/w12072032