Abstract
Livestock wastewater effluent generated after the anaerobic treatment process contains the considerable amount of color-causing organic matter. In this study, a quantitative comparison of three carbon-based adsorbents included granular activated carbon (GAC), expanded graphite (EG), and multi-walled carbon nanotubes (MWNTs) was carried out for the potential application to the removal of color substances, and their mechanism was proposed. Although GAC showed the highest specific dissolved organic carbon (DOC) adsorption capacity, the color removal efficiency was the smallest among three adsorbents. The selective color removal ratios of EG and MWNTs reached 22.7 ± 0.1 PtCo/mg-DOC-removed and 21.2 ± 0.1 PtCo/mg-DOC-removed, respectively, while that of GAC was only 12.3 ± 0.1 PtCo/mg-DOC-removed. The selective adsorption of color substances by graphene-based carbon materials was due to the aromatic π–π interaction between organic matter and the hexagonal carbon lattice of graphene. The analysis of molecular weight distribution also confirmed that the exposed surface area and macro-pores were responsible for the adsorption of high molecular weight color substances. The chemical regeneration of three adsorbents was examined using 1% NaOCl solution and MWNTs showed almost complete recovery of the initial color removal capacity. In conclusion, MWNTs were the most suitable carbon nanomaterial for the selective color removal from livestock wastewater effluent.
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Ahmad, A., & Hameed, B. (2009). Reduction of COD and color of dyeing effluent from a cotton textile mill by adsorption onto bamboo-based activated carbon. Journal of Hazardous Materials,172(2–3), 1538–1543.
Álvarez-Torrellas, S., Peres, J., Gil-Álvarez, V., Ovejero, G., & García, J. (2017). Effective adsorption of non-biodegradable pharmaceuticals from hospital wastewater with different carbon materials. Chemical Engineering Journal,320, 319–329.
Azmi, N. B., Bashir, M. J., Sethupathi, S., Wei, L. J., & Aun, N. C. (2015). Stabilized landfill leachate treatment by sugarcane bagasse derived activated carbon for removal of color, COD and NH3-N–optimization of preparation conditions by RSM. Journal of Environmental Chemical Engineering,3(2), 1287–1294.
Bhatnagar, A., & Sillanpää, M. (2017). Removal of natural organic matter (NOM) and its constituents from water by adsorption—A review. Chemosphere,166, 497–510.
Burakov, A. E., Galunin, E. V., Burakova, I. V., Kucherova, A. E., Agarwal, S., Tkachev, A. G., et al. (2018). Adsorption of heavy metals on conventional and nanostructured materials for wastewater treatment purposes: A review. Ecotoxicology and Environmental Safety,148, 702–712.
Chen, W., Westerhoff, P., Leenheer, J. A., & Booksh, K. (2003). Fluorescence excitation-emission matrix regional integration to quantify spectra for dissolved organic matter. Environmental Science and Technology,37(24), 5701–5710.
Collivignarelli, M. C., Abbà, A., Miino, M. C., & Damiani, S. (2019). Treatments for color removal from wastewater: State of the art. Journal of Environmental Management,236, 727–745.
Do, Q. C., & Kang, S. (2016). Thermodynamic analysis of fatty acid harvesting by novel carbon-based adsorbent. Environmental Science and Pollution Research,23(8), 7146–7154.
Do, Q. C., Kim, M.-S., Kim, D., Ko, S.-O., & Kang, S. (2016). Sustainable harvesting of aqueous phase fatty acids by expanded graphite and isopropyl alcohol. International Journal of Hydrogen Energy,41(46), 21780–21786.
Fan, S., Wang, Y., Wang, Z., Tang, J., Tang, J., & Li, X. (2017). Removal of methylene blue from aqueous solution by sewage sludge-derived biochar: Adsorption kinetics, equilibrium, thermodynamics and mechanism. Journal of Environmental Chemical Engineering,5(1), 601–611.
Ghaedi, M., Sadeghian, B., Pebdani, A. A., Sahraei, R., Daneshfar, A., & Duran, C. (2012). Kinetics, thermodynamics and equilibrium evaluation of direct yellow 12 removal by adsorption onto silver nanoparticles loaded activated carbon. Chemical Engineering Journal,187, 133–141.
Hyung, H., & Kim, J.-H. (2008). Natural organic matter (NOM) adsorption to multi-walled carbon nanotubes: Effect of NOM characteristics and water quality parameters. Environmental Science and Technology,42(12), 4416–4421.
Ip, A., Barford, J., & McKay, G. (2009). Reactive Black dye adsorption/desorption onto different adsorbents: Effect of salt, surface chemistry, pore size and surface area. Journal of Colloid and Interface Science,337(1), 32–38.
Jang, J. K., Jin, Y. J., Kang, S., Kim, T., Paek, Y., Sung, J. H., et al. (2017). Simultaneous removal of organic pollutants, nitrogen, and phosphorus from livestock wastewater by microbubble-oxygen in a single reactor. Journal of Korean Society of Environmental Engineers,39(11), 599–606.
Jiang, L., Liu, Y., Liu, S., Zeng, G., Hu, X., Hu, X., et al. (2017). Adsorption of estrogen contaminants by graphene nanomaterials under natural organic matter preloading: Comparison to carbon nanotube, biochar, and activated carbon. Environmental Science and Technology,51(11), 6352–6359.
Kai, H., Ishibashi, Y., Mori, T., Ishibashi, H., Kawaguchi, I., Ohwaki, H., et al. (2010). Decolorization and estrogenic activity of colored livestock wastewater after electrolysis treatment. Journal of Material Cycles and Waste Management,12(2), 128–135.
Karanfil, T., Schlautman, M. A., & Erdogan, I. (2002). Survey of DOC and UV measurement practices with implications for SUVA determination. Journal-American Water Works Association,94(12), 68–80.
Khaled, A., El Nemr, A., El-Sikaily, A., & Abdelwahab, O. (2009). Removal of Direct N Blue-106 from artificial textile dye effluent using activated carbon from orange peel: Adsorption isotherm and kinetic studies. Journal of Hazardous Materials,165(1–3), 100–110.
Kim, M., Park, K., & Kim, J. M. (2016). Phosphate recovery from livestock wastewater using iron oxide nanotubes. Chemical Engineering Research and Design,114, 119–128.
Kizito, S., Wu, S., Kirui, W. K., Lei, M., Lu, Q., Bah, H., et al. (2015). Evaluation of slow pyrolyzed wood and rice husks biochar for adsorption of ammonium nitrogen from piggery manure anaerobic digestate slurry. Science of the Total Environment,505, 102–112.
Kong, Y., Yuan, J., Wang, Z., Yao, S., & Chen, Z. (2009). Application of expanded graphite/attapulgite composite materials as electrode for treatment of textile wastewater. Applied Clay Science,46(4), 358–362.
Lee, J.-J. (2012). Adsorption equilibrium, kinetics and thermodynamics studies of malachite green using zeolite. Clean Technology,18(1), 76–82.
Lee, C.-Y., Jee, H.-S., Chung, J.-W., Kim, S.-H., Cho, Y.-C., & Kang, S.-T. (2012). Adsorption of p-Xylene by expanded graphite. Journal of the Korean Geoenvironmental Society,13(5), 35–40.
Li, Y., Du, Q., Liu, T., Peng, X., Wang, J., Sun, J., et al. (2013). Comparative study of methylene blue dye adsorption onto activated carbon, graphene oxide, and carbon nanotubes. Chemical Engineering Research and Design,91(2), 361–368.
Li, P., Gao, B., Li, A., & Yang, H. (2018). Highly selective adsorption of dyes and arsenate from their aqueous mixtures using a silica-sand/cationized-starch composite. Microporous and Mesoporous Materials,263, 210–219.
Li, Q., Snoeyink, V. L., Mariñas, B. J., & Campos, C. (2003). Pore blockage effect of NOM on atrazine adsorption kinetics of PAC: The roles of PAC pore size distribution and NOM molecular weight. Water Research,37(20), 4863–4872.
Mahmoodi, N. M., Salehi, R., & Arami, M. (2011). Binary system dye removal from colored textile wastewater using activated carbon: Kinetic and isotherm studies. Desalination,272(1–3), 187–195.
Noonpui, S., Thiravetyan, P., Nakbanpote, W., & Netpradit, S. (2010). Color removal from water-based ink wastewater by bagasse fly ash, sawdust fly ash and activated carbon. Chemical Engineering Journal,162(2), 503–508.
Ozsoy, H. D., & van Leeuwen, J. H. (2010). Removal of color from fruit candy waste by activated carbon adsorption. Journal of Food Engineering,101(1), 106–112.
Peng, M., Li, H., Li, D., Du, E., & Li, Z. (2017). Characterization of DOM adsorption of CNTs by using excitation–emission matrix fluorescence spectroscopy and multiway analysis. Environmental Technology,38(11), 1351–1361.
Riaño, B., Coca, M., & García-González, M. C. (2014). Evaluation of Fenton method and ozone-based processes for colour and organic matter removal from biologically pre-treated swine manure. Chemosphere,117, 193–199.
Sharma, Y. C., & Upadhyay, S. N. (2009). Removal of a cationic dye from wastewaters by adsorption on activated carbon developed from coconut coir. Energy & Fuels,23(6), 2983–2988.
Simonin, J.-P. (2016). On the comparison of pseudo-first order and pseudo-second order rate laws in the modeling of adsorption kinetics. Chemical Engineering Journal,300, 254–263.
Singh, S. K., Townsend, T. G., Mazyck, D., & Boyer, T. H. (2012). Equilibrium and intra-particle diffusion of stabilized landfill leachate onto micro-and meso-porous activated carbon. Water Research,46(2), 491–499.
Tak, B.-Y., Tak, B.-S., Kim, Y.-J., Park, Y.-J., Yoon, Y.-H., & Min, G.-H. (2015). Optimization of color and COD removal from livestock wastewater by electrocoagulation process: Application of Box–Behnken design (BBD). Journal of Industrial and Engineering Chemistry,28, 307–315.
Xiao, Y., & Hill, J. M. (2017). Impact of pore size on fenton oxidation of methyl orange adsorbed on magnetic carbon materials: Trade-off between capacity and regenerability. Environmental Science and Technology,51(8), 4567–4575.
Ye, Z.-L., Deng, Y., Lou, Y., Ye, X., Zhang, J., & Chen, S. (2017). Adsorption behavior of tetracyclines by struvite particles in the process of phosphorus recovery from synthetic swine wastewater. Chemical Engineering Journal,313, 1633–1638.
Zare, K., Gupta, V. K., Moradi, O., Makhlouf, A. S. H., Sillanpää, M., Nadagouda, M. N., et al. (2015). A comparative study on the basis of adsorption capacity between CNTs and activated carbon as adsorbents for removal of noxious synthetic dyes: A review. Journal of Nanostructure in Chemistry,5(2), 227–236.
Zhang, S., Shao, T., Kose, H. S., & Karanfil, T. (2010). Adsorption of aromatic compounds by carbonaceous adsorbents: A comparative study on granular activated carbon, activated carbon fiber, and carbon nanotubes. Environmental Science and Technology,44(16), 6377–6383.
Zhang, L., Wang, Y., Jin, S., Lu, Q., & Ji, J. (2017). Adsorption isotherm, kinetic and mechanism of expanded graphite for sulfadiazine antibiotics removal from aqueous solutions. Environmental Technology,38(20), 2629–2638.
Zhou, Q., Cabaniss, S. E., & Maurice, P. A. (2000). Considerations in the use of high-pressure size exclusion chromatography (HPSEC) for determining molecular weights of aquatic humic substances. Water Research,34(14), 3505–3514.
Acknowledgements
This research is supported by National Research Foundation under “Next Generation Carbon Upcycling Project” (Project No. 2017M1A2A2043150) of the Ministry of Science and ICT, Republic of Korea.
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Kim, H., Yun, YM., Lim, KH. et al. Selective removal of color substances by carbon-based adsorbents in livestock wastewater effluents. Environ Geochem Health 42, 1643–1653 (2020). https://doi.org/10.1007/s10653-020-00547-w
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DOI: https://doi.org/10.1007/s10653-020-00547-w