Insight on Extraction and Characterisation of Biopolymers as the Green Coagulants for Microalgae Harvesting
Abstract
:1. Introduction
2. The Promising Future of Microalgae
2.1. Microalgae as Next Generation of Biofuel
2.2. Bioprocess Approach of Microalgae Biofuel
3. Extraction of Natural Coagulants
3.1. Plant Based Polymers
3.1.1. Primary Processing
3.1.2. Secondary Processing
3.1.3. Tertiary Processing
3.2. Microbial Based Polymers
- Preliminary identification of the natural coagulants-producing bacterium strain based on its mucoid and ropy colony morphology characteristics.
- Screening of bacteria and fungi to find microbial-based coagulants from bacterium strain.
- Determining the flocculating activity of microbial-based coagulants (natural coagulants) yielded from each bacterium strain by kaolin clay suspension.
- Optimising the culture conditions of bacteria to produce a higher amount of natural coagulant.
3.3. Animal Based Polymers
4. Strategy to Enhance Performance of Natural Coagulants in Microalgae Harvesting
4.1. Physical Characteristics
4.2. Chemical Characteristics
4.3. Thermal Characteristics
5. Application of Natural Coagulant in Microalgae Harvesting
Natural Coagulant | Operating Condition | Performance | Reference |
---|---|---|---|
Alkyl-grafted chiton Fe3O4–SiO2 | 0.013 g·L−1 dosage | 90% removal of Chlorella vulgaris | [128] |
M. oleifera | 8 mg·L−1 dosage | 76% removal of Chlorella vulgaris | [129] |
M.oleifera with chitosan | 8 mg·L−1 dosage | 96% removal of Chlorella vulgaris | [129] |
F. indica | 12 mg·mL−1 dosage | 60% removal of microalgae | [130] |
Pleurotus ostreatus strain HEI-8 | pH 3, glucose content 20 g·L−1, fungi pelletisation time 7 days, 100 rpm | 65% removal of Chlorella sp. | [131] |
Citrobacter freundii (No. W4) and Mucor circinelloides | pH 7, glucose concentration 1.47g·L−1 | 97% removal of Chlorella pyrenoidosa | [132] |
Tannin | 11 mg·L−1 dosage, pH 5 to 7 | 97% removal of Chlorella vulgaris | [133] |
Tannin | 5 mg·L−1 dosage, pH 7 | 80% removal of Oocystis microalgae | [134] |
Eucalyptus globulus | 20 mg·L−1 dosage | 95% removal of Scenedesmus sp. | [135] |
Cassia gum | 80 mg·L−1 dosage | 93% removal of Chlamydomonas sp. | [136] |
Cassia gum | 35 mg·L−1 dosage | 92% removal of Chlorella sp. | [136] |
6. Cost analysis of Natural Coagulants in Microalgae Harvesting
7. Potentially New Natural Coagulant Yet to Be Exploited and Applied
8. Conclusions
Author Contributions
Funding
Acknowledgments
Conflicts of Interest
References
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Bacterial Strain | Flocculating Activity in Removal of Kaolin (%) | Reference |
---|---|---|
Bacillus agaradhaerens C9 | 81 | [49] |
Bacillus sp. XF-56 | 94 | [49] |
Arthrobacter sp. B4 | 99 | [50] |
Bacillus licheniformis X14 | 98 | [47,51] |
Bacillus velezensis 40B | >98 | [52] |
Chryseobacterium daeguense W6 | 97 | [48] |
Klebsiella sp. ZZ-3 | 95 | [53] |
Streptomyces sp. MBRC-91 | 96 | [54] |
Aspergillus flavus (source NI 3) | >90 | [55] |
Penicillum strain HHE-P7 | 96 | [47,56] |
Aspergillus flavus (source NI) | 97 | [55] |
Rhizopus sp. M9 & Rhizopus sp. M17 | 90 | [57] |
Talaromyces sp. | 93 | [58] |
Chitosan | Operating Condition | Flocculation Ability | Reference |
---|---|---|---|
Chitosan | 214 mg·L−1, pH 8 and 131 rpm | 92% removal of Chlorella vulgaris | [61] |
Chitosan (Plaemon serratus) | 15 mg·L−1 at 67 nephelometric turbidity units (NTU) raw water, flocculation time of 20 min | 89% removal of sewage wastewater | [62] |
Chitosan (shrimp) | 4 mg·L−1, pH 6 and flocculation time of 10 min | 95% removal of Thalassiosira pseudonana microalgae | [63] |
Chitosan | 30 mg·L−1, pH 7, flocculation time of 20 min | 98% removal of Chlorella vulgaris | [64] |
Chitosan | 4 mg·L−1, pH 4 and flocculation time of 10 min | 90% removal of Thalassiosira pseudonana microalgae | [63] |
Chitosan | 20 mg·L−1, pH 9.9, flocculation time of 10 min | 90% removal of Thalassiosira pseudonana microalgae | [63] |
Xanthated chitosan | 50 mg·L−1, pH 6.0, slow stirring for 10 min and settling for 10 min | >97% removal of Cu2+ | [65] |
Natural Coagulant | Surface Morphology | Surface Charge | Molecular Weight | Functional Group | Elemental Property | Thermogravimetry Analysis | Differential Scanning Calorimetry | Performance | Reference |
---|---|---|---|---|---|---|---|---|---|
Banana peel (Musa acuminate) | -N/A- | -N/A- | -N/A- | C=O, O-H, N–H | -N/A- | -N/A- | -N/A- | 0.4 g·L−1 dosage, 67% removal of chemical oxygen demand (COD) from municipal wastewater | [69] |
Banana pith | -N/A- | -N/A- | -N/A- | O-H, C-H, C-OO, C-H, COOH | O (44%), C (32%), (36 %), H (4.2%), N (1.5%), S (0.86%) | -N/A- | -N/A- | 0.1 kg·m−3 dosage, pH 4, 99% removal of COD from river water | [70] |
Brachystegia eurycoma extract | Compact structure with dispersed but continuous crack-like openings, absence of irregular surfaces, randomly formed aggregates and/or loosely bound cluster | -N/A- | -N/A- | O–H, N–H, O=H, C–N, C≡C, C=C–H and H–C–H | -N/A- | 334.44 °C to 361.73 °C | −1.708 mV | 5 g·L−1 dosage, pH 8, 97% removal of COD from paint wastewater | [71] |
Brassica spp. seed protein | Pollen grain surface | −6.8 mV | 6.5 kDa | -N/A- | -N/A- | 95 °C | -N/A- | -N/A- | [29,72] |
Cassava peel starch | Polygonal and spherical starch granules, rough surface | -4.37 mV | 1.057 × 105 kDa | O-H, C-H | Ca, K and Na | -N/A- | -N/A- | 7.5 mg·L−1 dosage, pH 7, 93% removal of total suspended solid (TSS) from dam water 50 mg·L−1 dosage, pH 7, 100% removal of E. coli from dam water | [73] |
Cactus leaves | Presence of cracks and cavities | -N/A- | -N/A- | O-H, C=O, COOH | Na, K, Ca, Mg | -N/A- | -N/A- | 10 mg·L−1 dosage, 90% removal of kaolin | [2,74] |
Cassava Peel (periderm and cortex) | Non-porous and heterogeneous characteristics, smooth and globular in shape | -N/A- | -N/A- | O-H, CH, CH2, C=O, C-O, COOH | K2O (5.5%), CaO (4.2%), Fe2O3 (1.5%), SO3 and SiO2 (0.87%), Al2O3 (0.74%), C (0.10%), | -N/A- | -N/A- | -N/A- | [75] |
Cassia obtusifolia seed gum | Fibrous networks with rough surface and porosity | -N/A- | -N/A- | O-H, C-H, C=O, | -N/A- | 289 °C | -N/A- | 2.47 g·L−1 dosage, 82% removal of TSS, settling time of 35.16 min | [76] |
Ceratonia silique seed gums | Rough cuticle on the adaxial and the abaxial surface, stomatal pores | -N/A- | 5–8 kDa | O-H | -N/A- | -N/A- | -N/A- | -N/A- | [29,77] |
Chitin | Microporous, fish scale shaped nanofibrous surface | +18 mV | -N/A- | N-H, O-H, C-H, C=O | -N/A- | -N/A- | -N/A- | 0.3 g·L−1 dosage, pH 6, 68% removal of turbidity from surface water | [78,79,80] |
Chitosan extracted from lobster shell (Thenus unimaculatus) | Rough surface, irregular block, crystalline with cluster and porosity structure | -N/A- | -N/A- | R-NH2, O-H | Ca, K, Na, Mg and Fe | -N/A- | -N/A- | -N/A- | [81,82] |
Citrus Limettioides peels | Porous structure | -N/A- | -N/A- | CH, CH2, CH3, C=O, COOH, M(RCOO)n, | O, Na, Ca | -N/A- | -N/A- | -N/A- | [75,83] |
C. obtusifolia seed gum | Rough, fibrous, porous and bulky | +6.41 mV | -N/A- | O-H, C-H, CH3, CH2 | -N/A- | 280–300 °C | -N/A- | 19 × 10−3 mol gum, 6 × 10−2 mol of NaOH, 87% removal of TSS and 85% removal of COD from palm oil mill effluent (POME) at 50 °C | [84,85] |
Cocos nucifera seed protein | Porous structure, clustered, aggregated shapes | -N/A- | 5.6 kDa | O-H, N-H | -N/A- | -N/A- | -N/A- | 10 g·L−1 dosage, 96% removal of As(III) in 8 h, 80 rpm and 50 °C | [29,86] |
Cucumis melo peels | -N/A- | -N/A- | 54 kDa | O-H, N-H, CH, CH2, CH3, C=O, R–COOH, M(RCOO)n, C-O or –C-N | -N/A- | -N/A- | -N/A- | 0.5 g·L−1 dosage, pH 7, 91% removal of Mn(II) 0.5 g·L−1 dosage, pH 6.5, 91% removal of Pb(II) | [75,87,88] |
Cyamopsis tetragonoloba seed gums | Nanoparticles | −6.66 mV | 50–800 kDa | O-H | -N/A- | -N/A- | -N/A- | -N/A- | [29,89] |
Dolichos lablab seed gums | Aggregated free, rough | -N/A- | -N/A- | N–H, O-H, C–H, C–C, –COOH | C, O | -N/A- | -N/A- | 0.6 mL·L−1 dosage, pH 11, 99% removal of turbidity | [29,90] |
Garden cress (Lepidium Sativum) | Flake-shaped structures with non-uniform distribution and emerged as interconnected channels, porous and heterogenous characteristics | −16 mV | -N/A- | O–H, C-H, C=O, OCH3 | -N/A- | -N/A- | -N/A- | 15 mg·L−1 dosage, pH 5, 99% removal of turbidity from river water | [91] |
Grafted 2-methacryloyloxyethyl trimethyl ammonium chloride lentil extract | More compact and less porous compared to lentil extract | +15.08 mV | -N/A- | -N/A- | C (62%), O (36%), Cl (2.0%) | -N/A- | -N/A- | 5.09 mL·g−1 dosage, pH 10, 99% removal of turbidity in surface water and industrial wastewater | [92] |
H. esculentus | Compact, cross linkage of molecules | -N/A- | 100 kDa | O–H, C–H, C=O | -N/A- | 180 °C | 36.12 mV | -N/A- | [3,93] |
Kenaf crude extract (KCE) | -N/A- | −8.3 mV | -N/A- | -N/A- | -N/A- | -N/A- | -N/A- | 100 mg·L−1 dosage, 85% removal of kaolin, 40 mg·L−1, 83% removal of turbidity from river water | [94] |
Klebsiella pneumoniae | -N/A- | -N/A- | -N/A- | COO−, O-H, N-H | C, N, O | -N/A- | -N/A- | pH 7, 40% removal of Cd | [2,95] |
Lens culinaris | Rough surface with pores and obvious surface abrasions | −3.58 mV | -N/A- | O–H, C-H, COOH, C=O, C-O | C (60%), O (40%), K (0.39%) | -N/A- | -N/A- | 26.3 mg·L−1 dosage, 99% removal of kaolin, 3 min settling time | [96] |
Lentil extract | Highly porous surface, scattered pieces of compounds attached | −5.91 mV | -N/A- | O–H, C-H, C=O, N-H, C-O-C | C (59%), O (39%) | 280 °C | -N/A- | -N/A- | [92] |
Maerua decumbent | -N/A- | -N/A- | -N/A- | O-H, C-H, N-H, C=O, C-O, C-N | C (39%), O (42%) H (3.8%), N (1.2%), S (0.31%) | -N/A- | -N/A- | 1 kg·m−3 dosage, pH 5.56, settling time 52.31 min, 99% removal of turbidity from paint industry wastewater 0.8 kg·m−3 dosage, pH 5.11, settling time 53.53 min, 79% removal of COD from paint industry wastewater | [1] |
Malva nut gum | A branch-like surface structure | −58.7 mV | 2.3 × 105 kDa | -N/A- | -N/A- | -N/A- | -N/A- | 0.06 mg·L−1 dosage, pH 3.01, 97% removal of kaolin | [97] |
Mango peels | Well-pronounced heterogeneous cavities that are well distributed | -N/A- | -N/A- | O-H, N-H, CH, CH2, CH3, C=O, C-O or –C-N | C, H, N, S | -N/A- | -N/A- | -N/A- | [75,98] |
Moringa oleifera | Group-like, composed of many small particles | +6 mV | 6.5 kDa | O-H, C-H, C=O, N-H, C-OH, S=O | -N/A- | -N/A- | -N/A- | 50 mg·L−1 dosage, 94% removal of kaolin | [2,94,99,100] |
Nirmali seeds | highly porous with reticulated structure | -N/A- | 12 kDa | COOH, O-H | -N/A- | -N/A- | -N/A- | 1.5 mg·L−1 dosage, 96% removal of turbidity from surface water | [2,101] |
okra | Porous and rough | −8.3 mV | -N/A- | -N/A- | Mg (7.2%), Al (4.1%), Si (3.7%), P (11.8%), S (8.2%), Cl (7.7%), K (22.0%), Ca (7.5%), O (27.8%) | -N/A- | -N/A- | 3 g·L−1 dosage, 85% removal of fluoride from hydrofluoric acid synthetic wastewater 20 mg·L−1 dosage, 94% removal of kaolin, 40 mg·L−1 dosage, 98% removal of turbidity from river water | [99] |
Prosopis spp. seed gums | Homogenous in size and shape with a flake-like morphology | -N/A- | 62 kDa | -N/A- | -N/A- | Ca, Mg, Fe, Zn | -N/A- | -N/A- | [29,94,102] |
Sabdariffa crude extract (SCE) | -N/A- | −6.4 mV | -N/A- | -N/A- | -N/A- | -N/A- | -N/A- | 60 mg·L−1 dosage, 88% removal of kaolin, 40 mg·L−1 dosage, 96% removal of turbidity from river water | [94] |
Sago | Smooth and solid surface with no pores | -N/A- | -N/A- | N-H, O-H, C=O | -N/A- | -N/A- | -N/A- | 0.1 g·L−1 dosage, pH 7, 69% removal of turbidity from surface water | [78] |
Tannin | -N/A- | −13.6 mV | 1250 kDa | O-H, R-NH2, C=O, COOH | -N/A- | 200 °C | -N/A- | 14 mg·L−1 dosage, 75% removal from kaolin 11 mg·L−1 dosage, pH 5 to 7, 97% removal of Chlorella vulgaris | [2,29,103] |
Tamarindus indica seed gums | No fissures, cracks or interruptions | -N/A- | 700–880 kDa | -N/A- | -N/A- | 97.67 °C | 128.40 J/g | 15 ppm dosage, 94% removal of turbidity from river water | [29,104,105] |
Telfairia occidentalis seed | Coarse fibrous substance largely composed of cellulose and lignin, presence of pores (micro-, macro- and mesopores, compact net structure | -N/A- | -N/A- | O-H, N-H, C=H | -N/A- | -N/A- | -N/A- | 247.40 mg·L−1 dosage, pH 2, 99% removal of dye in 34.32 mg·L−1 concentration with 540 settling time | [106,107] |
T. foenum graecum seed gums | -N/A- | -N/A- | 32.3 kDa | O-H, C-H, C=O, N-H, C-OH, C-O-C | C,O | 295 °C to 430 °C | -N/A- | -N/A- | [29,108] |
Vegetable tannin | -N/A- | -N/A- | -N/A- | -N/A- | -N/A- | 430 °C | -N/A- | pH 7, removal of color and turbidity from dairy wastewater | [109] |
Vigna unguiculata seed proteins | Fairly uniform, hexagonal structure, spiked or rugged surface, rough surface, coarse fibrous | -N/A- | 6 kDa | O-H, N-H, C=O, C=C-H, C=CH, C-H | -N/A- | -N/A- | -N/A- | 256.09 mg·L−1 dosage, pH 2, 99% removal of dye of 16.7 mg·L−1 with 540 min settling time | [29,106,107,110] |
Coagulant | Energy Consumption (Mega Joule per Metric Tons, MJ/MT of Microalgae) | Greenhouse Gas (GHG) Emission (kg CO2 eqv/MT of Microalgae) | Cost Analysis ($/MT) |
---|---|---|---|
Chitosan | 300 | 70 | 9.02 |
Alum | 200 | 50 | 0.28 |
Plant-based coagulant | 175 | 40 | 0.037 |
Possible Natural Coagulant | Scientific Name | Reference |
---|---|---|
Cowpea | Vigna unguiculata | [138] |
Chia seeds | Salvia hispanica L. | [139] |
Rockcress | Arabidopsis thaliana | [140] |
Quince seed | Cydonia oblonga | [141] |
Jujube | Ziziphus mauritiana Lam | [142] |
Seashore mallow | Kosteletzkya virginica | [143] |
Watershield | Brasenia schreberi | [144] |
Beet root | Alyssum homolocarpum | [145] |
Levant wormseed | Artemisia sphaerocephala | [146] |
Fenugreek seed | Trigonella foenum-graecum L. | [147] |
Cress seed | Lepidium sativum | [148] |
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Ang, T.-H.; Kiatkittipong, K.; Kiatkittipong, W.; Chua, S.-C.; Lim, J.W.; Show, P.-L.; Bashir, M.J.K.; Ho, Y.-C. Insight on Extraction and Characterisation of Biopolymers as the Green Coagulants for Microalgae Harvesting. Water 2020, 12, 1388. https://doi.org/10.3390/w12051388
Ang T-H, Kiatkittipong K, Kiatkittipong W, Chua S-C, Lim JW, Show P-L, Bashir MJK, Ho Y-C. Insight on Extraction and Characterisation of Biopolymers as the Green Coagulants for Microalgae Harvesting. Water. 2020; 12(5):1388. https://doi.org/10.3390/w12051388
Chicago/Turabian StyleAng, Teik-Hun, Kunlanan Kiatkittipong, Worapon Kiatkittipong, Siong-Chin Chua, Jun Wei Lim, Pau-Loke Show, Mohammed J. K. Bashir, and Yeek-Chia Ho. 2020. "Insight on Extraction and Characterisation of Biopolymers as the Green Coagulants for Microalgae Harvesting" Water 12, no. 5: 1388. https://doi.org/10.3390/w12051388
APA StyleAng, T. -H., Kiatkittipong, K., Kiatkittipong, W., Chua, S. -C., Lim, J. W., Show, P. -L., Bashir, M. J. K., & Ho, Y. -C. (2020). Insight on Extraction and Characterisation of Biopolymers as the Green Coagulants for Microalgae Harvesting. Water, 12(5), 1388. https://doi.org/10.3390/w12051388