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All issues Volume 302 (2021) E3S Web Conf., 302 (2021) 02018 References
Open Access
Issue
E3S Web Conf.
Volume 302, 2021
2021 Research, Invention, and Innovation Congress (RI2C 2021)
Article Number 02018
Number of page(s) 10
Section Environmental Science and Engineering
DOI https://doi.org/10.1051/e3sconf/202130202018
Published online 10 September 2021
  1. J.P. Broomfield, Corrosion of steel in concrete: understanding, investigation, and repair (2nd edition, CRC Press, Taylor & Francis Group, London, p. 296, 2019) [Google Scholar]
  2. W. Green, F. Collins, M. Forsyth, Up to date overview of aspects of steel reinforcement corrosion in concrete. In Brian Cherry paper series (The Australasian Corrosion Association Inc., 2020) [Google Scholar]
  3. ISO/TC 071, Strategic business plan (ISO Technical Committee, p. 11, 2016) [Google Scholar]
  4. C.R. Gagg, Cement and concrete as an engineering material: An historic appraisal and case study analysis, Engineering Failure Analysis, 40, (2014): 114-140 [Google Scholar]
  5. U.M. Angst, Challenges and opportunities in corrosion of steel in concrete, Materials and Structures, 51, (2018): 4 [Google Scholar]
  6. R.W. Revie, H.H. Uhlig, Corrosion and corrosion control: An introduction to corrosion science and engineering (4th edition, John Wiley and Sons, Inc., Hoboken New Jersey, USA, p. 490, 2008) [Google Scholar]
  7. J. Bhattarai, Frontiers of corrosion science (1st edition, Kshitiz Publication, Kirtipur, Kathmandu, Nepal, p. 304, 2010) [Google Scholar]
  8. B. Cherry, W. Green, Corrosion and protection of reinforced concrete (1st edition, CRC Press, Taylor & Francis Group, p. 402, 2021) [Google Scholar]
  9. J.O’M. Bockris, A.K.N. Reddy, Modern electrochemistry: Electrodics in chemistry, engineering, biology, and environmental science (2nd edition, volume 2B, Kluwer Academic/Plenum Publisher, New York, 2001) [Google Scholar]
  10. NPL, The corrosion of steel in concreteBasic understanding, monitoring and corrosion control methods (National Physical Laboratory, NPL Management Ltd., Middlesex, UK, p. 11, 2020) [Google Scholar]
  11. S.A. Asipita, M. Ismail, M.Z.A. Majid, Z.A. Majid, C. Abdullah, J. Mirza, Green Bambusa arundinacea leaves extract as a sustainable corrosion inhibitor in steel-reinforced concrete, Journal of Cleaner Production, 67, (2014): 139-146 [Google Scholar]
  12. C. Apostolopoulos, K. Koulouris, Corrosion effect on bond loss between steel and concrete (IntechOpen, p. 18, 2020) [Google Scholar]
  13. E.C. Seyhan, F. Goodwin, I.-W. Huang, Corrosion protection of steel reinforcement by using surface applied corrosion inhibitors, MATEC Web Conference, 289, (2019): 05001 [Google Scholar]
  14. K. Doi, S. Hiromoto, T. Shinohara, K. Tsuchiya, H. Katayama, E. Akiyama, Role of mill scale on corrosion behavior of steel rebars in mortar, Corrosion Science, 177, (2020): 108995 [Google Scholar]
  15. R. Cantone, M. Fernández Ruiz, A. Muttoni, A detailed view on the rebar-to-concrete interaction based on refined measurement techniques, Engineering Structures, 226, (2021): 111332 [Google Scholar]
  16. J.O. Okeniyi, J.O. Ikotun, E.T. Akinlabi, E.T. Okeniyi, Anticorrosion behaviour of Rhizophora mangles L. bark-extract on concrete steel-rebar in saline/marine simulating-environment, The Scientific World Journal, 2019, (2019): 6894714 [Google Scholar]
  17. J.O. Okeniyi, E.T. Akinlabi, J.O. Ikotun, S.A. Akinlabi, E.T. Okeniyi, O.M. Elizabeth, Rhizophora mangle L. leaf biochemical characterization: Natural green total corrosion inhibition prospect on concrete steel-reinforcement in 3.5 % NaCl, Jurnal Teknologi (Sciences & Engineering), 81, 1 (2019): 11-21 [Google Scholar]
  18. J.O. Okeniyi, C. Loto, A. Popoola, Effects of Phyllanthus muellerianus Leaf-extract on steelreinforcement corrosion in 3.5 % NaCl-immersed concrete, Metals, 6, 11 (2016): 255 [Google Scholar]
  19. Y.P. Asmara, T. Kurniawan, A.G.E. Sutjipto, J. Jamiluddin Jafar, Application of plants extracts as green corrosion inhibitors for steel in concretea review, Indonesian Journal of Science & Technology, 3, 2 (2018): 158-170 [Google Scholar]
  20. D.B. Left, M. Zertoubi, S. Khoudali, M. Azzi, New application of Chamaerops humilis L. extract as a green corrosion inhibitor for reinforcement steel in a simulated carbonated concrete pore solution, Portugaliae Electrochimica Acta, 36, 4 (2018): 249257 [Google Scholar]
  21. M. Ben Harb, S. Abubshait, N. Etteyeb, M. Kamoun, A. Dhouib, Olive leaf extract as a green corrosion inhibitor of reinforced concrete contaminated with seawater, Arabian Journal of Chemistry, 13, 3 (2020): 4846-4856 [Google Scholar]
  22. M. Zhang, Davidian involucrata Leaves extract as green corrosion inhibitor for low carbon steel in concrete pore solution containing chlorideions, International Journal of Electrochemical Science, 16, (2021): 21042 [Google Scholar]
  23. G. Xie, L. Wei, Inhibitor effect of Anthocleista djalonensis extract on the corrosion of concrete steel reinforcement, International Journal of Electrochemical Science, 13, (2018): 5311–5322. [Google Scholar]
  24. V.S. Helbert, L. Gaillet, T. Chaussadent, V. Gaudefroy, J. Creus, Rhamnolipids as an eco-friendly corrosion inhibitor of rebars in simulated concrete pore solution: Evaluation of conditioning and addition methods, Corrosion Engineering, Science and Technology, 55, 2 (2020): 91-102 [Google Scholar]
  25. R. Anitha, S. Chitra, V. Hemapriya, I.M. Chung, S.H. Kim, M. Prabakaran, Implications of eco-addition inhibitor to mitigate corrosion in reinforced steel embedded in concrete, Construction and Building Materials, 213, (2019): 246-256 [Google Scholar]
  26. C.A. Loto, O.O. Joseph, R.T. LotoA. P.I. Popoola, Inhibition effect of Vernonia amygdalina extract on the corrosion of mild steel reinforcement in concrete in 3.5 M NaCl environment, International Journal of Electrochemical Science, 8, 9 (2013): 11087-11100 [Google Scholar]
  27. R.A. Limco, H.P. Bacosa, A.A. Lubguban, J.S. Buluran, Morinda citrifolia (Noni) leaf extract as corrosion inhibitor for steel-reinforced concrete in saline environment, International Journal of Environmental Science and Technology, 17, (2020): 4531-4540 [Google Scholar]
  28. J.A. Selvi, M. Arthanareeswari, T. Pushpamalini, S. Rajendran, T. Vignesh, Effectiveness of Vinca rosea Leaf extract as corrosion inhibitor for mild steel in 1 N HCl medium investigated by adsorption and electrochemical studies, International Journal of Corrosion and Scale Inhibition, 9, 4 (2020): 1429-1443 [Google Scholar]
  29. R.M.A. Shahba, A.E.E. Fouda, A.E. El-Shenawy, A.S.M. Osman, Effect of Catharanthus roseus (Vince rosea) and turmeric (Curcuma longa) extracts as green corrosion inhibitors for mild steel in 1 M HCl, Materials Sciences and Applications, 7, (2016): 654-671 [Google Scholar]
  30. K. Hema, B.R. Venkatraman, A. Subramania, Aqueous extract of Vitex negundo Leaves as green corrosion inhibitor for the protection of carbon steel in 1 N HCl solution, Journal of Environmental Nanotechnology, 4, 3 (2013): 42-50 [Google Scholar]
  31. N. Palaniappan, I. Cole, F. Caballero-Briones, S. Manickam, K.R. Justin Thomas, D. Santos, Experimental and DFT studies on the ultrasonic energy-assisted extraction of the phytochemicals of Catharanthus roseus as green corrosion inhibitors for mild steel in NaCl medium, RSC Advances, 10, (2020): 5399-5411 [Google Scholar]
  32. M. Rana, S. Joshi, J. Bhattarai, Extract of different plants of Nepalese origin as a green corrosion inhibitor for mild steel in 0.5 M NaCl solution, Asian Journal of Chemistry, 29, 5 (2017): 1130-1134 [Google Scholar]
  33. Savita, P. Mourya, N. Chaubedi, V.K. Singh, M.M. Singh, Eco-friendly inhibitors for copper corrosion in nitric acid: Experimental and theoretical evaluation, Metallurgical and Materials Transactions B, 47, 1 (2016): 47-57 [Google Scholar]
  34. S. Sirajunnisa, M.I. Fazal Mohamed, A. Subramania, Vitex negundo Leaves extract as green inhibitor for the corrosion of aluminium 1 N NaOH solution, Journal of Chemical and Pharmaceutical Research, 6, (2014): 580-588 [Google Scholar]
  35. B.N. Subedi, K. Amgain, S. Joshi, J. Bhattarai, Green approach to corrosion inhibition effect of Vitex negundo leaf extract on aluminium and copper metals in biodiesel and its blend, International Journal of Corrosion and Scale Inhibition, 8, 3 (2019): 744–759 (2019) [Google Scholar]
  36. P. Katuwal, R. Regmi, S. Joshi, J. Bhattarai, Assessment on the effective green-based Nepal origin plants extract as corrosion inhibitor for mild steel in bioethanol and its blend, European Journal of Advanced Chemistry Research, 1, 5 (2020): 1-13 [Google Scholar]
  37. N.R. Phulara, J. Bhattarai, Assessment on corrosion damage of steel reinforced concrete structures of Kathmandu Valley using corrosion potential mapping method, Journal of the Institute of Engineering, 15, 2 (2019): 47-56 [Google Scholar]
  38. I. Laudari, N.R. Phulara, M. Gautam, J. Bhattarai, Evaluation on the corrosion condition of some steelreinforced concrete infrastructures available in Pokhara valley of Nepal, Tribhuvan University Journal, (2021): in press [Google Scholar]
  39. J. Bhattarai, D. Paudyal, K. P. Dahal, Study on the soil corrosivity towards the buried-metallic pipes in Kathmandu and Chitwan valley of Nepal. In Proceedings of the 17th Asian-Pacific Corrosion Control Conference (Paper No. 17039, 27-30 January, 2016, IIT Bombay, India, p. 12) [Google Scholar]
  40. P.P. Bhandari, K.P. Dahal, J. Bhattarai, The Corrosivity of soil collected from Araniko Highway and Sanothimi areas of Bhaktapur, Journal of Institute of Science and Technology, 18, 1 (2013): 71-77 [Google Scholar]
  41. K.P. Dahal, J.N. Timilsena, M. Gautam, J. Bhattarai, Investigation on probabilistic model for corrosion failure level of buried-pipelines in Kirtipur urban areas (Nepal), Journal of Failure Analysis and Prevention, 21, 3 (2021): 914-926 [Google Scholar]
  42. K.P. Dahal, R.K. Karki, J. Bhattarai, Evaluation of corrosivity of soil collected from the central part of Kathmandu Metropolis (Nepal) to water supply metallic pipes, Asian Journal of Chemistry, 30, 7 (2018): 1525-1530 [Google Scholar]
  43. Y.P. Dhakal, K.P. Dahal, J. Bhattarai, Investigation on the soil corrosivity towards the buried water supply pipelines in Kamerotar Town Planning areas of Bhaktapur, Nepal, Bibechana, 10, (2014): 82-91 [Google Scholar]
  44. A. Poudel, K.P. Dahal, J. Bhattarai, A classification approach for corrosion rating of soil to buried water pipelines: A case study in BudhanilkanthaMaharajganj roadway areas of Nepal, World Journal of Applied Chemistry, 5, 3 (2020): 47–56 (2020) [Google Scholar]
  45. S.K. Regmi, K.P. Dahal, J. Bhattarai, Soil corrosivity to the buried-pipes used in Lalitpur, Kathmandu Valley, Nepal, Nepal Journal of Environmental Science, 3, 1 (2015): 15-20 [Google Scholar]
  46. J. Bhattarai, An overview on the non-destructive indepth surface analysis of corrosion-resistant films: A case study of W-xCr deposits in 12 M HCl solution, Bibechana, 18, 1 (2021): 201-213 [Google Scholar]
  47. J. Bhattarai, Review on in-depth analysis of the passive films of W-xTi alloys by angle-resolved Xray photoelectron spectroscopy, Science Journal of Chemistry, 8, 2 (2020): 28-35 [Google Scholar]
  48. ASTM C876-15, Standard test method for corrosion potentials of uncoated reinforcing steel in concrete (ASTM International, West Conshohocken, PA, USA, p. 8, 2015) [Google Scholar]
  49. ASTM C1582 / C1582M-11, Standard specification for admixtures to inhibit chloride-induced corrosion of reinforcing steel in concrete (ASTM International, West Conshohocken, USA, pp. 10, 2017) [Google Scholar]
  50. T.M.B. Bandiola, Extraction and qualitative phytochemical screening of medicinal plants: a brief summary, International Journal of Pharmacy, 8, 1 (2018): 137-143 [Google Scholar]
  51. A. Flores-Nicolas, M. Flores-Nicolas, J. UruchurtuChavarin, Corrosion effect on reinforced concrete with the addition of graphite powder and its evaluation on physical-electrochemical properties, Revista ALCONPAT, 11, 1 (2021): 18-33 [Google Scholar]
  52. N. Koirala, C. Dhakal, N.N. Munankarmi, S.W. Ali, A. Hameed, N. Martins, J. Sharifi-Rad, M. Imran, A.M. Arif, M.S. Hanif, B. Salehi, (2020). Vitex negundo Linn: phytochemical composition, nutritional analysis, and antioxidant and antimicrobial activity. Cellular and Molecular Biology (Noisy-le-Grand, France), 66, 4 (2020): 1-7 [Google Scholar]
  53. S. Saklani, A.P. Mishra, H. Chandra, M.S. Atanassova, M. Stankovic, B. Sati, M.A. Shariati, M. Nigam, M.U. Khan, S. Plygun, H. Elmsellem, H.A.R. Suleria, Comparative evaluation of polyphenol contents and antioxidant activities between ethanol extracts of Vitex negundo and Vitex trifolia L. leaves by different methods, Plants, 6, 4 (2017): 45 [Google Scholar]
  54. S.C. Ohadoma, H.U. Michael, Effects of coadministration of methanol leaf extract of Catharanthus roseus on the hypoglycemic activity of metformin and glibenclamide in rats, Asian Pacific Journal of Tropical Medicine, 4, 6 (2011): 475-477 [PubMed] [Google Scholar]
  55. M.K. Dwivedi, R. Shukla, N.K. Sharma, A. Manhas, K. Srivastava, N. Kumar, P.K Singh, Evaluation of ethnopharmacologically selected Vitex negundo L. for In vitro antimalarial activity and secondary metabolite profiling, Journal of Ethnopharmacology, 275, (2021): 114076 [PubMed] [Google Scholar]
  56. A. Kalaiselvi, S.M. Roopan, G. Madhumitha, C. Ramalingam, G. Elango, Synthesis and characterization of palladium nanoparticles using Catharanthus roseus leaf extract and its application in the photo-catalytic degradation, Spectrochimica ActaPart A: Molecular and Biomolecular Spectroscopy, 135, (2015): 116-119 [Google Scholar]
  57. R. Ylmen, U. Jaglid, I. Panas, Monitoring early hydration of cement by ex situ and in situ ATRFTIR– a comparative study, Journal of the American Ceramic society, 97, 11 (2014): 3669-3675 [Google Scholar]
  58. E.V. Tararushkin, T.N. Shchelokova, V.D. Kudryavtseva, A study of strength fluctuations of Portland cement by FTIR spectroscopy, IOP Conference Series: Materials Science and Engineering, 919, (2020): 022017 [Google Scholar]
  59. J. Higl, D. Hinder, C. Rathgeber, B. Ramming, M. Lindén, Detailed in situ ATR-FTIR spectroscopy study of the early stages of C-S-H formation during hydration of monoclinic C3S, Cement and Concrete Research, 142, (2021): 106367 [Google Scholar]
  60. A.A. Al-Amiery, M.H.O. Ahmed, T.A. Abdullah, T.S. Gaaz, A.A.H. Kadhum, Electrochemical studies of novel corrosion inhibitor for mild steel in 1 M hydrochloric acid, Results in Physics, 9, (2018): 978-981 [Google Scholar]
  61. A. Kadhim, A.K. Al-Okbi, D.M. Jamil, A. Qussay, A.A. Al-Amiery, T.S. Gaaz, T. S., … M.H. Nassir, Experimental and theoretical studies of benzoxazines corrosion inhibitors, Results in Physics, 7, (2017): 4013-4019 [Google Scholar]
  62. N.U. Shehu, U.I. Gaya, A.A. Muhammad, Influence of side chain on the inhibition of aluminium corrosion in HCl by α-amino acids, Applied Science and Engineering Progress, 12, 3 (2019): 187-197 [Google Scholar]

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