Evaluate to remove azo dye Chrysoidine Y of activated carbon material produced from bamboo leaves

  • Cơ quan:

    Hanoi University of Mining and Geology, Hanoi, Vietnam

  • *Tác giả liên hệ:
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  • Nhận bài: 06-12-2021
  • Sửa xong: 25-03-2022
  • Chấp nhận: 10-05-2022
  • Ngày đăng: 30-06-2022
Trang: 26 - 34
Lượt xem: 4188
Lượt tải: 2360
Yêu thích: 1.0, Số lượt: 235
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Tóm tắt:

Activated carbons (ACs) are well known as the most commonly used adsorbent in water and wastewater treatment. They have many advantage characteristics such as high surface area, large pores and diverse surface functional groups with the high stability of chemical, mechanical and thermal. The aims of this study are to fabricate and evaluate the ability to remove the azo dye Chrysoidine Y in the water of three activated carbon materials from bamboo leaves, including AC30 (6500C/30 minutes); AC45 (6500C/45 minutes) and AC60 (6500C/60 minutes). The material characteristics determined by SEM, EDX, FTIR and BET methods, etc. showed that all three samples had high C content (over 72%) and appeared functional groups with the capacity of removing azo dye as C = C; C - O - C, O - H. The FTIR results indicated that three samples have adsorption spectra from 400÷4000 cm-1 with characteristic bonds such as C = O, O - H, C - C, C = C. When 20 ml of a solution containing 0.25; 0.5; 1 and 2 g of AC30, AC45 and AC60 materials were added the azo dye volume varied from 2, 3, 4 and 5 ml of Chrysoidine Y, the lowest and highest adsorption capacity were recorded of 133.64 and 361.2 mg/g, respectively. With the highest BET surface area up to 108,9202 m2/g, the AC60 material sample achieved a maximum efficiency of 100% at a reaction time of 30 minutes with a Chysoidine dye/distilled water volume ratio of 2/18 (ml), pH 9, adsorbent content of 0.25 g. The results also showed that the activated carbon from bamboo leaves is a potential sorbent material in removing the azo dye in water.

Trích dẫn
Huong Thu Thi Tran và Ha Kim Thi Tran, 2022. Evaluate to remove azo dye Chrysoidine Y of activated carbon material produced from bamboo leaves, Tạp chí Khoa học kỹ thuật Mỏ - Địa chất, số 63, kỳ 3, tr. 26-34.
Tài liệu tham khảo

Abd-Elhamid, A. I., Emran, M., El-Sadek, M. H., El-Shanshory, A. A., Soliman, H. M. A., Akl, M. A., Rashad, M., (2020). Enhanced removal of cationic dye by eco-friendly activated biochar derived from rice straw. Applied Water Science 10(1). 45. 

Aboel-Zahab, H., El-Khyat, Z., Sidhom, G., Awadallah, R., Abdel-Al, W., Mahdy, K., (1997). Physiological effects of some synthetic food colouring additives on rats. Bollettino Chimico Farmaceutico 136(10). 615-627 

Ahmad, A., Khan, N., Giri, B. S., Chowdhary, P., Chaturvedi, P., (2020). Removal of methylene blue dye using rice husk, cow dung and sludge biochar: Characterization, application and kinetic studies. Bioresource Technology 306. 123202. 

Amirza, M. A. R., Adib, M. M. R., Hamdan, R., (2017). Application of Agricultural Wastes Activated Carbon for Dye Removal - An Overview. MATEC Web of Conferences 103. 06013.

Benkhaya, S., M’rabet, S., El Harfi, A., (2020). Classifications, properties, recent synthesis and applications of azo dyes. Heliyon 6(1). e03271. 

Chan, L. S., Cheung, W. H., McKay, G., (2008). Adsorption of acid dyes by bamboo derived activated carbon. Desalination 218(1-3). 304-312.

Cui, J., Yang, Y., Hu, Y., Li, F., (2015). Rice husk based porous carbon loaded with silver nanoparticle by a simple and cost-effective approach and their antibacterial activity. Journal of Colloid and Interface Science 455. 117-124.

Dias, Y. N., Souza, E. S., da Costa, H. S. C., Melo, L. C. A., Penido, E. S., do Amarante, C. B., Teixeira, O. M. M., Fernandes AR (2019). Biochar produced from Amazonian agro-industrial wastes: properties and adsorbent potential of Cd2+ and Cu2+. Biochar 1. 389-400. 

Elmaguana, Y., Elhadiri, N., Benchanaa, M., Chikri, R., (2020). Activated Carbon for Dyes Removal: Modeling and Understanding the Adsorption Process. Journal of Chemistry 2020. 1-9. 

Fei, B., Gao, Z., Wang, J., Liu, Z., (2016). Biological, Anatomical and Chemical Characteristics of Bamboo. Economic Application of Secondary Xylem. 283-306.

Hameed, B. H., El-Khaiary, M. I., (2008). Equilibrium, kinetics and mechanism of malachite green adsorption on activated carbon prepared from bamboo by K2CO3 activation and subsequent gasification with CO2. Journal of Hazardous Materials 157(2-3). 344-351.

Hao, Y., Wang, Z., Gou, J., Dong, S., (2015). Highly efficient adsorption and removal of Chrysoidine Y from aqueous solution by magnetic graphene oxide nanocomposite. Arabian Journal of Chemistry 12(8). 3064 -3074.

Hirata, M., Kawasaki, N., Nakamura, T., Matsumoto, K., Kabayama, M., Tamura, T., Tanada, S., (2002). Adsorption of dyes onto carbonaceous materials produced from coffee grounds by microwave treatment. Journal of Colloid and Interface Science 254. 17-22.

Kaya, N., Uzun, Z. Y., (2020). Investigation of effectiveness of pyrolysis products on removal of alizarin yellow GG from aqueous solution: a comparative study with commercial activated carbon. Water Science and Technology 81. 1191-1208.

Khamis, M. I., Ibrahim, T. H., Jumean, F. H., Sara, Z. A., Atallah, B. A., (2020). Cyclic Sequential Removal of Alizarin Red S Dye and Cr(VI) Ions Using Wool as a Low-Cost Adsorbent. Processes 8(5). 556. 

Kornaros, M., Lyberatos, G., (2006). Biological treatment of wastewaters from a dye manufacturing company using a trickling filter. Journal of Hazardous Materials 136(1). 95-102.

Krishna Mohan, G. V., Naga Babu, A., Kalpana, K., Ravindhranath, K., (2016). Removal of naphthol green B dye from polluted waters using hydrogen peroxide treated red mud. Der Pharma Chemica 8(19). 403-414. 

Kyi, P. P., Quansah, J. O., Lee, C. G., Moon, J. K., Park, S. J., (2020). The Removal of Crystal Violet from Textile Wastewater Using Palm Kernel Shell-Derived Biochar. Applied Sciences 10(7). 2251. 

Laskar, N., Kumar, U., (2018). Removal of Brilliant Green dye from water by modified Bambusa Tulda: adsorption isotherm, kinetics and thermodynamics study. International Journal of Environmental Science and Technology 16. 1649-1662.

Lee, J. W., Choi, S. P., Thiruvenkatachari, R., Shim, W. G., Moon, H., (2006). Submerged microfiltration membrane coupled with alum coagulation/powdered activated carbon adsorption for complete decolorization of reactive dyes. Water Research 3. 435-444. 

Macedo, JdS., Júnior, N. B. dC., Almeida, L. E., Vieira, E. F. dS., Cestari, A. R., Gimenez, I. dF., (2006). Kinetic and calorimetric study of the adsorption of dyes on mesoporous activated carbon prepared from coconut coir dust. Journal of Colloid and Interface Science 298. 515-522.

Mahdi, Z., El Hanandeh, A., Yu, Q., (2017). Influence of pyrolysis conditions on surface characteristics and methylene blue adsorption of biochar derived from date seed biomass. Waste and Biomass Valorization 8. 2061-2073.

Oveisi, M., Asli, M. A., Mahmoodi, N. M., (2018). MIL-Ti metal-organic frameworks (MOFs) nanomaterials as superior adsorbents: synthesis and ultrasound-aided dye adsorption from multicomponent wastewater systems. The Journal of Hazardous Materials 347. 123-140. 

Pavia, D. L., Lampman, G. M., Kriz, G. S., Vyvyan, J. R., (2013). Introduction to spectroscopy. In book. Printed in the United States of America

Saeed, A., Sharif, M., Iqbal, M., (2010). Application potential of grapefruit peel as dye sorbent: kinetics, equilibrium and mechanism of crystal violet adsorption. Journal of Hazardous Materials 179(1-3). 564-572.

Srinivasan, A., Viraraghavan, T., (2010). Decolorization of dye wastewaters by biosorbents: A review. Journal of Environmental Management 91(10). 1915-1929. 

Tran, T. T. H., Nguyen, V. H., Vu, N. T., Nguyen, X. T., Tran, A. Q., Vu, K. T., (2021). Initial Results of Using Biochar Derived from Spent Coffee Grounds to Remove Pollutants from Livestock Wastewater in Vietnam. In book: Proceedings of the International Conference on Innovations for Sustainable and Responsible Mining 108. 305-325.

Tran, T. T. H., Vu, N. T., Pham, T. N., Nguyen, X. T., (2021). Ability to remove azo dye from textile dyeing wastewaters of carbonaceous materials produced from bamboo leaves. Title Book: Novel Materials for Dye-containing Wastewater Treatment, Sustainable Textiles: Production, Processing, Manufacturing and Chemistry, 185-208.

Vu, T. M., Trinh, V. T., Doan, D. P., Van, H. T., Nguyen, T. V., Vigneswaran, S., Ngo, H. H., (2017). Removing ammonium from water using modified corncob-biochar. Science of The Total Environment 579. 612-619.

Yang, G., Wu, L., Xian, Q., Shen, F., Wu, J., Zhang, Y., (2016). Removal of Congo Red and Methylene Blue from Aqueous Solutions by Vermicompost-Derived Biochars. PLOS ONE 11(5). e0154562.

Zhu, Y., Yi, B., Yuan, Q., Wu, Y., Wang, M., Yan, S., (2018). Removal of methylene blue from aqueous solution by cattle manure-derived low temperature biochar. RSC Advances 8(36). 19917-19929.

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