Conversion of lignocellulosic waste into effective flocculants: synthesis, characterization, and performance

Elham Jahedi; Reza Panahi

doi:10.1186/s40643-021-00422-1

Bioresources and Bioprocessing ›› 2021, Vol. 8 ›› Issue (1) : 69 DOI: 10.1186/s40643-021-00422-1

Research

Conversion of lignocellulosic waste into effective flocculants: synthesis, characterization, and performance

Elham Jahedi ¹
, Reza Panahi ¹^,^b

Author information +

History +

PDF

Abstract

Development of cationic flocculants from lignocellulosic wastes not only eliminates the health and environmental concerns associated with the use of conventional chemicals, but also is the way of waste valorization. In the present study, cellulose fibers extracted from rice husk were cationized through an optimization method based on response surface methodology. The fibers cationized at the optimal conditions had a zeta-potential of 15.2 ± 1.0 mV, while the highest potential was + 8.76 mV, for the samples developed before optimization. FTIR analysis proved the presence of the corresponding functional groups. The functionalized fibers were biodegradable and had absolutely positive surface charges at a broad pH range. The cationized fibers were employed as a flocculant to remove turbidity from the synthetic wastewaters at various pHs and initial turbidities. The cationic fibers showed the excellent turbidity removals up to 98.5% from the synthetic wastewater without the need for conventional coagulants. In contrast to traditionally cationized fibers, the synthesized flocculants did not affect the effluent color during coagulation–flocculation. The charge neutralization and bridging through adsorption were the governing mechanisms of flocculation. The procedure can be applied on lignocellulosic wastes to develop cationic fibers with the excellent flocculation ability and suitable operational characteristics.

Keywords

Cationization / Cellulose fibers / Flocculation mechanism / Natural flocculant / Rice husk / Turbidity removal

Cite this article

Download citation ▾

Elham Jahedi, Reza Panahi. Conversion of lignocellulosic waste into effective flocculants: synthesis, characterization, and performance. Bioresources and Bioprocessing, 2021, 8(1): 69 DOI:10.1186/s40643-021-00422-1

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Abdollahi K, Yazdani F, Panahi R. Covalent immobilization of tyrosinase onto cyanuric chloride crosslinked amine-functionalized superparamagnetic nanoparticles: Synthesis and characterization of the recyclable nanobiocatalyst. Int J Biol Macromol, 2017, 94: 396-405.

[2]	Abdollahi K, Yazdani F, Panahi R. Fabrication of the robust and recyclable tyrosinase-harboring biocatalyst using ethylenediamine functionalized superparamagnetic nanoparticles: nanocarrier characterization and immobilized enzyme properties. J Biol Inorg Chem, 2019, 24: 943-959.

[3]	Abdollahi K, Yazdani F, Panahi R, Mokhtarani B. Biotransformation of phenol in synthetic wastewater using the functionalized magnetic nano-biocatalyst particles carrying tyrosinase. 3 Biotech, 2018, 8: 419.

[4]	Aguado R, Lourenco AF¸ Ferreira PJ, Moral A, Tijero A, . Cationic cellulosic derivatives as flocculants in papermaking. Cellulose, 2017, 24: 3015-3027.

[5]	Akhlaghi SP, Zaman M, Mohammed N, Brinatti C, Batmaz R, Berry R, Loh W, Tam KC. Synthesis of amine functionalized cellulose nanocrystals: Optimization and characterization. Carbohydr Res, 2015, 409: 48-55.

[6]	Das R, Ghorai S, Pal S. Flocculation characteristics of polyacrylamide grafted hydroxypropyl methyl cellulose : An efficient biodegradable flocculant. Chem Eng J, 2013, 229: 144-152.

[7]	Du Q, Wei H, Li A, Yang H. Evaluation of the starch-based flocculants on flocculation of hairwork wastewater. Sci Total Environ, 2017, 601–602: 1628-1637.

[8]	Ebrahimi M, Panahi R, Dabbagh R. Evaluation of native and chemically modified Sargassum glaucescens for continuous biosorption of Co(II). Appl Biochem Biotechnol, 2009, 158: 736-746.

[9]	Farasat Z, Panahi R, Mokhtarani B. Timecourse study of coagulation-flocculation process using aluminum sulfate. Water Conserv Manage, 2017, 1: 7-9.

[10]	Ferasat Z, Panahi R, Mokhtarani B. Natural polymer matrix as safe flocculant to remove turbidity from kaolin suspension: Performance and governing mechanism. J Environ Manage, 2020, 255: 109939.

[11]	Gao BY, Xu X, Wang Y, Yue QY, Xu XM. Preparation and characteristics of quaternary amino anion exchanger from wheat residue. J Hazard Mater, 2009, 165: 461-468.

[12]	Gregory J, Barany S. Adsorption and flocculation by polymers and polymer mixtures. Adv Colloid Interface Sci, 2011, 169: 1-12.

[13]	Hospodarova V, Singovszka E, Stevulova N. Characterization of cellulosic fibers by FTIR spectroscopy for their further implementation to building materials. Am J Analyt Chem, 2018, 9: 303-310.

[14]	Johar N, Ahmad I, Dufresne A. Extraction preparation and characterization of cellulose fibres and nanocrystals from rice husk. Ind Crops Prod, 2012, 37: 93-99.

[15]	Lapointe M, Barbeau B. Dual starch–polyacrylamide polymer system for improved flocculation. Water Res, 2017, 124: 202-209.

[16]	Li M, Wang Y, Hou X, Wan X, Xiao H-N. DMC-grafted cellulose as green-based flocculants for agglomerating fine kaolin particles. Green Energy Environ, 2018, 3: 138-146.

[17]	Liimatainen H, Sirviö J, Sundman O, Visanko M, Hormi O, Niinimäki J. Flocculation performance of a cationic biopolymer derived from a cellulosic source in mild aqueous solution. Bioresour Technol, 2011, 102: 9626-9632.

[18]	Liu Z, Huang M, Li A, Yang H. Flocculation and antimicrobial properties of a cationized starch. Water Res, 2017, 119: 57-66.

[19]	Ma J, Fu K, Fu X, Guan Q, Ding L, Shi J, Zhu G, Zhang X, Zhang S, Jiang L. Flocculation properties and kinetic investigation of polyacrylamide with different cationic monomer content for high turbid water purification. Sep Purif Technol, 2017, 182: 134-143.

[20]	Mandels M, Weber J. The Production of Cellulases. Adv Chem, 1969, 95: 391-414.

[21]	Matilainen A, Vepsäläinen M, Sillanpää M. Natural organic matter removal by coagulation during drinking water treatment: A review. Adv Colloid Interface Sci, 2010, 159: 189-197.

[22]	Nourani M, Baghdadi M, Javan M, Bidhendi GN. Production of a biodegradable flocculant from cotton and evaluation of its performance in coagulation-flocculation of kaolin clay suspension: Optimization through response surface methodology (RSM). J Environ Chem Eng, 2016, 4: 1996-2003.

[23]	Oliveira JP, de Bruni GP, Lima KO, El Rosa HSLM, da Dias GS, ARG, Zavareze E da R, . Cellulose fibers extracted from rice and oat husks and their application in hydrogel. Food Chem, 2017, 221: 153-160.

[24]	Prat D, Wells A, Hayler J, Sneddon H, McElroy CR, Abou-Shehada S, Dunn PJ. CHEM21 selection guide of classical- and less classical-solvents. Green Chem, 2016, 18: 288.

[25]	Sirviö J, Honka A, Liimatainen H, Niinimäki J, Hormi O. Synthesis of highly cationic water-soluble cellulose derivative and its potential as novel biopolymeric flocculation agent. Carbohydr Polym, 2011, 86: 266-270.

[26]	Soltani Firooz N, Panahi R, Mokhtarani B, Yazdani F. Direct introduction of amine groups into cellulosic paper for covalent immobilization of tyrosinase: support characterization and enzyme properties. Cellulose, 2017, 24: 1407-1416.

[27]	Taherzadeh-Ghahfarokhi M, Panahi R, Mokhtarani B. Optimizing the combination of conventional carbonaceous additives of culture media to produce lignocellulose-degrading enzymes by Trichoderma reesei in solid state fermentation of agricultural residues. Renew Energy, 2019, 131: 946-955.

[28]	Taherzadeh-Ghahfarokhi M, Panahi R, Mokhtarani B. Medium supplementation and thorough optimization to induce carboxymethyl cellulase production by Trichoderma reesei under solid state fermentation of nettle biomass. Prep Biochem Biotechnol, 2021

[29]	Tang H, Xiao F, Wang D. Speciation stability and coagulation mechanisms of hydroxyl aluminum clusters formed by PACl and alum: A critical review. Adv Colloid Interface Sci, 2015, 226: 78-85.

[30]	Tassinari B, Doherty S, Marison IW. Submicron capsules extracted from rapeseed as novel flocculant agents for the treatment of turbid water. Water Res, 2013, 47: 4957-4965.

[31]	Vijan V, Kaity S, Biswas S, Isaac J, Ghosh A. Microwave assisted synthesis and characterization of acrylamide grafted gellan application in drug delivery. Carbohydr Polym, 2012, 90: 496-506.

[32]	Yan L, Tao H, Bangal PR. Synthesis and flocculation behavior of cationic cellulose prepared in a NaOH/urea aqueous solution. Clean-Soil Air Water, 2009, 37: 39-44.

[33]	Yang R, Li H, Huang M, Yang H, Li A. A review on chitosan-based flocculants and their applications in water treatment. Water Res, 2016, 95: 59-89.

[34]	Zhang H, Guo H, Wang B, Xiong L, Shi S, Chen X. Homogeneous synthesis and characterization of polyacrylamide-grafted cationic cellulose flocculants. J Appl Polym Sci, 2016, 133: 6-11.

[35]	Zhuang J, Li M, Pu Y, Ragauskas AJ, Yoo CG. Observation of potential contaminants in processed biomass using Fourier transform infrared spectroscopy. Appl Sci, 2020, 10: 4345.