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http://dx.doi.org/10.4191/kcers.2016.53.4.429

Use of Calcined Oyster Shell Powders as CO2 Adsorbents in Algae-Containing Water  

Huh, Jae-Hoon (R&D Team, Hanil Cement Corporation)
Choi, Young-Hoon (R&D Team, Advanced Materials and Technology Lab., Daesung MDI)
Ramakrishna, Chilakala (R&D Team, Hanil Cement Corporation)
Cheong, Sun Hee (Department of Marine Bio Food Science, College of Fisheries and Ocean Science, Chonnam National University)
Ahn, Ji Whan (Carbon Resource Recycling Appropriate Technology Center, Korea Institute of Geoscience and Mineral Resources)
Publication Information
Journal of the Korean Ceramic Society / v.53, no.4, 2016 , pp. 429-434 More about this Journal
Abstract
Here, we introduce a means of utilizing waste oyster shells which were obtained from temporary storage near coastal workplaces as $CO_2$ adsorbents. The calcined CaO can be easily dissociated to $Ca^{2+}$ cation and $CO_3{^{2-}}$ anion by hydrolysis and gas-liquid carbonation reaction and converted to precipitated calcium carbonate (PCC) in algae-containing water. The calcium hydroxide and carbonation combination in algae-containing water significantly contributed to improving water quality which is very dependent on the addition amount of calcined powders.
Keywords
Carbon dioxide; Adsorbent; Calcined oyster shell; Carbonation; Algae-containing water;
Citations & Related Records
Times Cited By KSCI : 2  (Citation Analysis)
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1 V. Ramanathan and Y. Feng, "Air Pollution, Greenhouse Gases and Climate Change: Global and Regional Perspectives," Atmos. Environ., 43 37-50 (2009).   DOI
2 D. S. Reay, E. A. Davidson, K. A. Smith, P. Smith, J. M. Melillo, F. Dentener, and P. J. Crutzen, "Global Agriculture and Nitrous Oxide Emissions," Nat. Clim. Change, 2 410-16 (2012).   DOI
3 Y. Liu, Z. U. Wang, and H.-C. Zhou, "Recent Advances in Carbon Dioxide Capture with Metal-Organic Frameworks," Greenhouse Gases: Sci. Technol., 2 239-59 (2012).   DOI
4 A. Robbins, "How to Understand the Results of the Climate Change Summit: Conference of Parties 21 (COP21) Paris 2015," J. Public Health Policy, 37 129-32 (2016).   DOI
5 M. Zhao, M. Bilton, A. P. Brown, A. M. Cunliffe, E. Dvininov, V. Dupont, T. P. Comyn, and S. J. Milne, "Durability of $CaO-CaZrO_3$ Sorbents for High-Temperature $CO_2$ Capture Prepared by a Wet Chemical Method," Energy Fuels, 28 1275-83 (2014).   DOI
6 R. Molinder, T. P. Comyn, N. Hondow, J. E. Parker, and V. Dupont, "In Situ X-ray Diffraction of CaO Based $CO_2$ Sorbents," Energy Environ. Sci., 5 8958-69 (2012).   DOI
7 C.-H. Yu, C.-H. Huang, and C.-S. Tan, "A Review of $CO_2$ Capture by Absorption and Adsorption," Aerosol Air Qual. Res., 12 745-69 (2012).
8 S.-Y. Pan, E.E. Chang and P.-C. Chiang, "$CO_2$ Capture by Accelerated Carbonation of Alkaline Waste: A Review on Its Principles and Applications," Aerosol Air Qual. Res., 12 770-91 (2012).   DOI
9 Y.-H. Choi, J.-H. Huh, S.-H. Lee, C. Han, J.-W. Ahn, "Preparation of Spherical Granules of Dolomite Kiln Dust as Gas Adsorbent," J. Korean Ceram. Soc., 53 [1] 13-7 (2016).   DOI
10 N. Chen, Z. Zhang, C. Feng, D. Zhu, Y. Yang and N. Sugiura, "Preparation and Characterization of Porous Granular Ceramic Containing Dispersed Aluminum and Iron Oxides as Adsorbents for Fluoride Removal from Aqueous Solution," J. Hazard. Mater., 186 863-68 (2011).   DOI
11 J.-H. Jung, K.-S. Yoo, H.-G. Kim, H.-K. Lee, and B.-H. Shon, "Reuse of Waste Oyster Shells as a $SO_2/NO_x$ Removal Absorbent," J. Ind. Eng. Chem., 13 [4] 512-17 (2007).
12 G.-L. Yoon, B.-T. Kim, B.-O. Kim, and S.-H. Han, "Chemical-Mechanical Characteristics of Crushed Oyster-Shell," J. Waste Manage., 23 825-34 (2003).   DOI
13 E.-I. Yang, S.-T. Yi, and Y.-M. Leem, "Effect of Oyster Shell Substituted for Fine Aggregate on Concrete Characteristics: Part I. Fundamental Properties," Cem. Concr. Res., 35 2175-82 (2005).   DOI
14 V. A. Juvekar and M. M. Sharma, "Adsorption of $CO_2$ in a Suspension of Lime," Chem. Eng. Sci., 28 825-37 (1973).   DOI
15 A. Biasin, C. U. Segre and M. Strumendo, "$CaCO_3$ Crystallite Evolution during CaO Carbonation: Critical Crystallite Size and Rate Constant Measurement by In-Situ Synchrotron Radiation X-Ray Powder Diffraction" Cryst. Growth Des., 15 5188-201 (2015).   DOI
16 J.-H. Huh, Y.-H. Choi, and J.-W. Ahn, "Limestone Particles for Algae Treatment (in Korean)," Ceramist, 18 [3] 5-13 (2015).
17 W. Li, W.-S. Chen, P.-P. Zhou, L. Cao, and L.-J. Yu, "Influence of Initial pH on the Precipitation and Crystal Morphology of Calcium Carbonate Induced by Microbial Carbonic Anhydrase," Colloids Surf., B, 102 281-87 (2013).   DOI
18 J. D. Rodriguez-Blanco, S. Shaw, and L. G. Benning, "The Kinetics and Mechanisms of Amorphous Calcium Carbonate (ACC) Crystallization to Calcite, via Vaterite," Nanoscale, 3 265-71 (2011).   DOI
19 J.-H. Huh, Y.-H. Choi, H.-J. Lee, W. J. Choi, C. Ramakrishna, H.-W. Lee, S.-H. Lee, and J.-W. Ahn, "The Use of Oyster Powders for Water Quality Improvement of Lakes by Algal Blooms Removal," J. Korean Ceram. Soc., 53 [1] 1-6 (2016).   DOI
20 Y. Du, Q. Meng, R. Hou, J. Yan, H. Dai, and T. Zhang, "Fabrication of Nano-Sized $Ca(OH)_2$ with Excellent Adsorption Ability for $N_2O_4$," Particuology, 10 737-43 (2012).   DOI
21 O. Cizer, C. Rodriguez-Navarro, E. Ruiz-Agudo, J. Elsen, D. V. Gemert, and K. V. Balen, "Phase and Morphology Evolution of Calcium Carbonate Precipitated by Carbonation of Hydrated Lime," J. Mater. Sci., 47 6151-65 (2012).   DOI
22 M. J. Al-Jeboori, P. S. Fennell, M. Nguyen, and K. Feng, "Effects of Different Dopants and Doping Procedures on the Reactivity of CaO-based Sorbents for $CO_2$ Capture," Energy Fuels, 26 6584-94 (2012).   DOI