Tropical Tannin for Engineering Application

https://doi.org/10.22146/ijc.40877

Nor Adzwa Binti Rosli(1*), Wan Asma Ibrahim(2), Zulkafli Hassan(3), Azizul Helmi Bin Sofian(4)

(1) Faculty of Chemical and Natural Resources Engineering, Universiti Malaysia Pahang, Lebuhraya Tun Razak 26300, Gambang, Pahang, Malaysia
(2) Forest Research Institute Malaysia (FRIM), 52109 Kepong, Selangor Darul Ehsan, Malaysia
(3) Faculty of Chemical and Natural Resources Engineering, Universiti Malaysia Pahang, Lebuhraya Tun Razak 26300, Gambang, Pahang, Malaysia
(4) Faculty of Chemical and Natural Resources Engineering, Universiti Malaysia Pahang, Lebuhraya Tun Razak 26300, Gambang, Pahang, Malaysia
(*) Corresponding Author

Abstract


In this study, some approaches have been proposed to establish an alternative and option of brand-new compounds by using green sources that can minimize the environmental threat in the engineering application industry. Tannin, a chemical component extracted from plant origin, has the potential to bind with proteins and other polymers. The description of tannin can be amplified to cover a complete mass of constituents which give typical phenolic reactions, and hence, it has the properties to interact with the aqueous solution. The potential of tannin to associate allows its usability in the oil and gas industry. The aim of this review in this particular context will be emphasized the use of tannin in the implementation of drilling fluid, mercury removal, wastewater treatment, and corrosion inhibitor.

Keywords


tannin; corrosion inhibition; drilling fluid; mercury; wastewater

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References

[1] Rana, M.S., Tyagi, A., Hossain, S.A., and Tyagi, A.K., 2012, Effect of tanniniferous Terminalia chebula extract on rumen biohydrogenation, Δ9-desaturase activity, CLA content and fatty acid composition in Longissimus dorsi muscle of kids, Meat Sci., 90 (3), 558–563.

[2] Bendary, E., Francis, R.R., Ali, H.M.G., Sarwat, M.I., and El Hady, S., 2013, Antioxidant and structure-activity relationships (SARs) of some phenolic and anilines compounds, Ann. Agric. Sci., 58 (2), 173–181.

[3] Ramakrishnan, K., and Krishnan, M.R.V., 1994, Tannin - Classification, analysis, and applications, Anc. Sci. Life, 13 (3-4), 232–238.

[4] Kushwaha, R., Rai, S.N., Singh, A.K., Chandra, G., Vaidya, M.M., Sharma, V.K., Pathan, M.M., and Kumar, S., 2007, Tanniniferous feed resources in dairy animals: A review, Agric. Rev., 32 (4), 267–275.

[5] Rahim, A.A., 2005, Physico-Chemical Characterisation of Mangrove Tannins as Corrosion Inhibitors, Dissertation, Universiti Sains Malaysia.

[6] Izawa, K., Amino, Y., Kohmura, M., Ueda, Y., and Kuroda, M., 2010, “Human–Environment Interaction – Taste”, in Comprehensive Natural Products II: Chemistry and Biology, Volume 4, Eds., Mander, L., and Liu, H.W., Elsevier Science, 631–671.

[7] Aldred, E., 2009, Pharmacology, A Handbook for Complementary Healthcare Professionals 1st ed., Churchill Livingstone, 149.

[8] Vijayaraghavan, G., Sivakumar, T., and Kumar, A.V., 2011, Application of plant-based coagulants for waste, IJAERS, 1 (1), 88–92.

[9] Gupta, A.K, 2008, Tannin Based Wood Adhesive, Niir Project Consultancy Products: Nirr Project Consultancy Services, New Delhi, India, 56–59.

[10] Dargahi, M., Olsson, A.L.J., Tufenkji, N., and Gaudreault, R., 2015, Green technology: Tannin-based corrosion inhibitor for protection of mild steel, Corrosion, 71 (11), 1321–1329.

[11] Wheatley, M.J., 2001, “Use of Tannins Adhesives Applications, Industrial Problems and Potentials” in Plant Polyphenols, Springer, Boston, USA, 1005–1011.

[12] Dariva, C.G., and Galio, A.F., 2014, “Corrosion Inhibitors–Principles, Mechanisms and Applications” in Development in Corrosion Protection, IntechOpen, London, 365–376.

[13] Shah, A.M., Rahim, A.A., Hamid, S.A., and Yahya, S., 2013, Green inhibitors for copper corrosion by mangrove tannin, Int. J. Electrochem. Sci., 8, 2140–2153.

[14] Oki, M., Charles, E., Alaka, C., and Oki, T.K., 2011, Corrosion inhibition of mild steel in hydrochloric acid by tannins from Rhizophora racemosa, Mater. Sci. Appl., 2, 592–595.

[15] Talib, N.A.A., Zakaria, S., Hua, C.C., and Othman, N.K., 2014, Tannin bark Melalauca cajuputi Powell (gelam) as green corrosion inhibitor of mild steel, AIP Conf. Proc., 1416, 171–177.

[16] Idora, M.S.N., Quen, L.K., and Kang, H.S., 2017, Effect of tannin from Rhizophora apiculate as corrosion inhibitor for epoxy paint on mild steel, J. Phys. Conf. Ser., 890, 012062.

[17] Nik, W.B.W., Jahar, H.M., Idora, M.S.N., Suriani, M.J., and Yabuki, A., 2015, Effect of mangrove bark condensed tannins (Rhizophora apiculata) as corrosion inhibitor for mild steel in simulated splash zone, J. Sci. Res. Dev., 2 (13), 59–63.

[18] Rahim, A.A., Rocca, E., Steinmetz, J., Adnan, R., and Kassim, J.N., 2004, Mangrove tannins as corrosion inhibitors in acidic medium–Study flavanoid monomers, EUROCORR 2004–European Corrosion Conference: Long Term Prediction and Modelling of Corrosion, 12–16 September 2004, Nice, France.

[19] Peres, R.S., Cassel, E., and Azambuja, D.S., 2012, Black wattle tannin as steel corrosion inhibitor, ISRN Corros., 2012, 937920.

[20] Negm, N.A., Badr, E.A., Tawfik, S.M., and El Farargy, A.F., 2014, Performance of nonionic surfactants derived from tannic acid in preventing the acidic dissolution of carbon steel, IOSR J Appl. Chem., 7 (6), 31–42.

[21] Tovar, C.T., Ortiz, Á.V., and Jaraba, L.E.G., 2015, Kinetics of adsorption in mercury removal using cassava (Manhiot esculenta) and lemon (Citrus limonum) wastes modified with citric acid, Ing. Univ., 19 (2), 283–298.

[22] Drake, L.R., and Rayson, G.D., 1996, Plant-derived materials for metal ion selective binding and preconcentration, Anal. Chem., 68 (1), 22A–27A.

[23] Pizzi, A., 1980, Tannin-based adhesives, J. Macromol. Sci., Polym. Rev., 18 (2), 247–315.

[24] Huang, X., Liao, X., and Shi, B., 2009, Hg(II) removal from aqueous solution by bayberry tannin-immobilized collagen fiber, J. Hazard. Mater., 170 (2-3), 1141–1148.

[25] Torres, J., Olivares, S., De La Rosa, D., Lima, L., Martínez, F., Munita, C.S., Favaro, D.I.T., 1999, Removal of mercury (II) and methyl mercury from solution by tannin adsorbents, J. Radioanal. Nucl. Chem., 240 (1), 361–365.

[26] Vázquez, G., González-Álvarez, J., Freire, S., López-Lorenzo, M., and Antorrena, G., 2002, Removal of cadmium and mercury ions from aqueous solution by sorption on treated Pinus pinaster bark: Kinetics and isotherms, Bioresour. Technol., 82 (3), 247–251.

[27] Yurtsever, M., and Şengil, İ.A., 2009, Biosorption of Pb(II) ions by modified quebracho tannin resin, J. Hazard. Mater., 163 (1), 58–64.

[28] Agarwal, H., Sharma, D., Sindhu, S.K., Tyagi, S., and Ikram, S., 2010, Removal of mercury from wastewater use of green adsorbents - A review, Electron. J. Environ. Agric. Food Chem., 9 (9), 1551–1558.

[29] Anirudhan, T.S., and Suchithra, P.S., 2008, Synthesis and characterization of tannin-immobilized hydrotalcite as a potential adsorbent of heavy metal ions in effluent treatments, Appl. Clay Sci., 42 (1-2), 214–223.

[30] Leme, F.P., 1990, Teoria e técnicas de tratamento de água, Rio de Janeiro: ABES, 540–564.

[31] Thakur, S.S., and Choubey, S., 2014, Use of tannin based natural coagulants for water treatment: An alternative to inorganic chemicals, Int. J. ChemTech Res., 6 (7), 3628–3634.

[32] Özacar, M.A., and Şengil, İ.A., 1997, Spectrophotometric methods for the estimation of tannins in plant tissues, Proceeding of XI, National Chemistry Congress, Van, 502.

[33] Steiner, P.R., 1989, “Tannins as Specialty Chemicals: An Overview” in Chemistry and Significance of Condensed Tannins, Eds., Hemingway, R.W., Karchesy, J.J., and Branham, S.J., Springer, Boston, 517–523.

[34] Caby, D., 2018, Oilfield Solutions, http://www.oilfield-solutions.basf.com/ev/internet/oilfield-solutions/en_GB/applications/drilling/thinners.

[35] Bax, N.K., 2015, Waste Management and Control, CreateSpace Independent Publishing Platform, U.S., 15.

[36] Ibrahim, M.N.M., Chuah, S.B., and Cheng, P.Y., 2003, Tin-tannin-lignosulfonate complex: An improved lignosulfonate based drilling fluid thinner, Jurnal Teknologi, 38 (3), 25–32.

[37] Hussein, A.S., Ibrahim, K.I., and Abdulla, K.M., 2011, Tannin-phenol formaldehyde resins as binders for cellulosic fibers: Mechanical properties, Nat. Resour., 2 (2), 98–101.

[38] Santana, M.A.E., Baumann, M.G.D., and Conner, A.H., 1995, Resol resins prepared with tannin liquified in phenol, Holzforschung, 49 (2), 146–152.

[39] Konai, N., Raidandi, D., Pizzi, A., Girods, P., Lagel, M.C., and Kple, M., 2016, Thermogravimetric analysis of anningre tannin resin, Maderas, Cienc. Tecnol., 18 (2), 245–252.

[40] Tondi, G., 2017, Tannin-based copolymer resins: Synthesis and characterization by solid state 13C NMR and FT-IR spectroscopy, Polymers, 9, 223–240.

[41] Chaieb, E., Bouyanzer, A., Hammouti, B., and Berrabah, M., 2009, Limonene as green inhibitor for steel corrosion in hydrochloric acid solutions, Acta Phys. Chim. Sin., 25 (7), 1254–1258.



DOI: https://doi.org/10.22146/ijc.40877

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