<?xml version="1.0" encoding="utf-8"?>
<XML>
	<JOURNAL>
		<YEAR>2020</YEAR>
		<VOL>2</VOL>
		<NO>4</NO>
		<MOSALSAL>4</MOSALSAL>
		<PAGE_NO>53</PAGE_NO>
		<ARTICLES>


			<ARTICLE>
				<LANGUAGE_ID>1</LANGUAGE_ID>
				<TitleF>-</TitleF>
				<TitleE>Synthesis and characterization of the novel 80S bioactive glass:
					bioactivity, ‎biocompatibility, cytotoxicity</TitleE>
				<URL>https://jourcc.com/index.php/jourcc/article/view/jcc231</URL>
				<DOI>10.29252/jcc.2.3.1</DOI>
				<DOR/>
				<ABSTRACTS>
					<ABSTRACT>
						<LANGUAGE_ID>1</LANGUAGE_ID>
						<CONTENT>In this research, the 80S bioactive glass with different Ca/P
							ratios was prepared by the sol-gel route. Scanning electron microscopy
							(SEM), transmission electron microscopy (TEM), energy dispersive
							spectroscopy (EDS), X-ray diffraction (XRD), and Fourier transforms
							infrared spectroscopy (FTIR) were used to study the apatite structure
							and shape. According to the results, the 78SiO2–17P2O5–5CaO bioglass
							showed a higher rate of crystalline hydroxyapatite (HA) on its surface
							in comparison with the other bioglasses. After 3 days of immersion in
							the SBF solution, spherical apatite was formed on the 78SiO2–17P2O5–5CaO
							surface, which demonstrated high bioactivity. A statistically
							significant promotion in proliferation and differentiation of G292
							osteoblastic cells was also observed. Regarding its optimal cell
							viability and bioactivity, the 78SiO2–17P2O5–5CaO bioactive glass could
							be offered as a promising candidate for bone tissue
							applications.</CONTENT>
					</ABSTRACT>
					<ABSTRACT>
						<LANGUAGE_ID>0</LANGUAGE_ID>
						<CONTENT>-</CONTENT>
					</ABSTRACT>
				</ABSTRACTS>
				<PAGES>
					<PAGE>
						<FPAGE>110</FPAGE>
						<TPAGE>114</TPAGE>
					</PAGE>
				</PAGES>

				<AUTHORS>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Ameneh</NameE>
						<MidNameE/>
						<FamilyE>Bakhtiari</FamilyE>
						<Organizations>
							<Organization>Department of Biology, Shahid Chamran
								University</Organization>
						</Organizations>
						<Countries>
							<Country>Iran</Country>
						</Countries>
						<EMAILS>
							<Email>info@jourcc.com</Email>
						</EMAILS>
					</AUTHOR>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Amir</NameE>
						<MidNameE/>
						<FamilyE>Cheshmi</FamilyE>
						<Organizations>
							<Organization>Department of Materials Engineering, Babol Noshirvani
								University of Technology</Organization>
						</Organizations>
						<Countries>
							<Country>Iran</Country>
						</Countries>
						<EMAILS>
							<Email>info@jourcc.com</Email>
						</EMAILS>
					</AUTHOR>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Maryam</NameE>
						<MidNameE/>
						<FamilyE>Naeimi</FamilyE>
						<Organizations>
							<Organization>School of Nursing and Midwifery, Tehran University of
								Medical Science</Organization>
						</Organizations>
						<Countries>
							<Country>Iran</Country>
						</Countries>
						<EMAILS>
							<Email>info@jourcc.com</Email>
						</EMAILS>
					</AUTHOR>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Sobhan Mohammadi</NameE>
						<MidNameE/>
						<FamilyE>Fathabad</FamilyE>
						<Organizations>
							<Organization>Department of Engineering and High-Tech, Iran University
								of Industries and Mines</Organization>
						</Organizations>
						<Countries>
							<Country>Iran</Country>
						</Countries>
						<EMAILS>
							<Email>info@jourcc.com</Email>
						</EMAILS>
					</AUTHOR>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Maryam</NameE>
						<MidNameE/>
						<FamilyE>Aliasghari</FamilyE>
						<Organizations>
							<Organization>Young Researchers and Elite Club, Yadegar-e-Imam Khomeini
								(RAH) Shahr-e-Rey Branch, Islamic Azad University</Organization>
						</Organizations>
						<Countries>
							<Country>Iran</Country>
						</Countries>
						<EMAILS>
							<Email>info@jourcc.com</Email>
						</EMAILS>
					</AUTHOR>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Amir</NameE>
						<MidNameE/>
						<FamilyE>Modarresi Chahardehi</FamilyE>
						<Organizations>
							<Organization>Advanced Medical and Dental Institute, Universiti Sains
								Malaysia</Organization>
						</Organizations>
						<Countries>
							<Country>Malaysia</Country>
						</Countries>
						<EMAILS>
							<Email>amirmch@gmail.com</Email>
						</EMAILS>
					</AUTHOR>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Sahar</NameE>
						<MidNameE/>
						<FamilyE>Hassani</FamilyE>
						<Organizations>
							<Organization>Department of Cellular and Molecular Biology, Tehran
								Medical Sciences, Islamic Azad University</Organization>
						</Organizations>
						<Countries>
							<Country>Iran</Country>
						</Countries>
						<EMAILS>
							<Email>info@jourcc.com</Email>
						</EMAILS>
					</AUTHOR>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Vahideh</NameE>
						<MidNameE/>
						<FamilyE>Elhami</FamilyE>
						<Organizations>
							<Organization>Sustainable Process Technology Group, University of
								Twente</Organization>
						</Organizations>
						<Countries>
							<Country>Netherlands</Country>
						</Countries>
						<EMAILS>
							<Email>info@jourcc.com</Email>
						</EMAILS>
					</AUTHOR>
				</AUTHORS>
				<KEYWORDS>
					<KEYWORD>
						<KeyText>Bioactive glass</KeyText>
					</KEYWORD>
					<KEYWORD>
						<KeyText>80S</KeyText>
					</KEYWORD>
					<KEYWORD>
						<KeyText>Ca/P ratio</KeyText>
					</KEYWORD>
					<KEYWORD>
						<KeyText>Hydroxyapatite</KeyText>
					</KEYWORD>
				</KEYWORDS>
				<REFRENCES>
					<REFRENCE>
						<REF>[1] L. Bazli, H. Nargesi khoramabadi, A. Modarresi Chahardehi, H.
							Arsad, B. Malekpouri, M. Asgari Jazi, N. Azizabadi, Factors influencing
							the failure of dental implants: A Systematic Review, Composites and
							Compounds 2(1) (2020). ## [2] A. Esmaeilkhanian, F. Sharifianjazi, A.
							Abouchenari, A. Rouhani, N. Parvin, M. Irani, Synthesis and
							characterization of natural nano-hydroxyapatite derived from turkey
							femur-bone waste, Applied biochemistry and biotechnology 189(3) (2019)
							919-932. ## [3] A. Chlanda, P. Oberbek, M. Heljak, E.
							Kijeńska-Gawrońska, T. Bolek, M. Gloc, Ł. John, M. Janeta, M.J. Woźniak,
							Fabrication, multi-scale characterization and in-vitro evaluation of
							porous hybrid bioactive glass polymer-coated scaffolds for bone tissue
							engineering, Materials Science and Engineering: C 94 (2019) 516-523. ##
							[4] E. Sharifi Sedeh, S. Mirdamadi, F. Sharifianjazi, M. Tahriri,
							Synthesis and evaluation of mechanical and biological properties of
							scaffold prepared from Ti and Mg with different volume percent,
							Synthesis and Reactivity in Inorganic, Metal-Organic, and Nano-Metal
							Chemistry 45(7) (2015) 1087-1091. ## [5] S. Rahimi, F. SharifianJazi, A.
							Esmaeilkhanian, M. Moradi, A.H.S. Samghabadi, Effect of SiO2 content on
							Y-TZP/Al2O3 ceramic-nanocomposite properties as potential dental
							applications, Ceramics International (2020). ## [6] S. Nasibi, K.
							Alimohammadi, L. Bazli, S. Eskandarinezhad, A. Mohammadi, N. Sheysi,
							TZNT alloy for surgical implant applications: A Systematic Review,
							Journal of Composites and Compounds 2(3) (2020) 61-67. ## [7] L. Bazli,
							B. Eftekhari Yekta, A. Khavandi, Preparation and Characterization of
							Sn-Containing Glasses for Brachytherapy Applications, Transactions of
							the Indian Ceramic Society 76(4) (2017) 242-246. ## [8] F.
							Sharifianjazi, A.H. Pakseresht, M.S. Asl, A. Esmaeilkhanian, H.W. Jang,
							M. Shokouhimehr, Hydroxyapatite consolidated by zirconia: applications
							for dental implant, Journal of Composites and Compounds 2(1) (2020)
							26-34. ## [9] Z. Goudarzi, A. Ijadi, A. Bakhriari, S. Eskandarinezhad,
							N. Azizabadi, M.A. Jazi, Sr-doped bioactive glasses for biological
							applications, Journal of Composites and Compounds 2(3) (2020) 105-109.
							## [10] J. Daraei, Production and characterization of PCL
							(Polycaprolactone) coated TCP/nanoBG composite scaffolds by sponge foam
							method for orthopedic applications, Journal of Composites and Compounds
							2(1) (2020) 45-50. ## [11] Z. Goudarzi, N. Parvin, F. Sharifianjazi,
							Formation of hydroxyapatite on surface of SiO2– P2O5–CaO–SrO–ZnO
							bioactive glass synthesized through sol-gel route, Ceramics
							International 45(15) (2019) 19323-19330. ## [12] F. Sharifianjazi, N.
							Parvin, M. Tahriri, Formation of apatite nano-needles on novel gel
							derived SiO2-P2O5-CaO-SrO-Ag2O bioactive glasses, Ceramics International
							43(17) (2017) 15214-15220. ## [13] K. Zhang, Q. Van Le, Bioactive glass
							coated zirconia for dental implants: a review, Journal of Composites and
							Compounds 2(1) (2020) 10-17. ## [14] F. Sharifianjazi, N. Parvin, M.
							Tahriri, Synthesis and characteristics of sol-gel bioactive
							SiO2-P2O5-CaO-Ag2O glasses, Journal of Non-Crystalline Solids 476 (2017)
							108-113. ## [15] M.S.N. Shahrbabak, F. Sharifianjazi, D. Rahban, A.
							Salimi, A comparative investigation on bioactivity and antibacterial
							properties of sol-gel derived 58S bioactive glass substituted by Ag and
							Zn, Silicon 11(6) (2019) 2741-2751. ## [16] F. Sharifianjazi, M. Moradi,
							A. Abouchenari, A.H. Pakseresht, A. Esmaeilkhanian, M. Shokouhimehr,
							M.S. Asl, Effects of Sr and Mg dopants on biological and mechanical
							properties of SiO2–CaO–P2O5 bioactive glass, Ceramics International
							(2020). ## [17] F. Sharifianjazi, A.H. Pakseresht, M. Shahedi Asl, A.
							Esmaeilkhanian, H. Nargesi khoramabadi, H.W. Jang, M. Shokouhimehr,
							Hydroxyapatite Consolidated by Zirconia: Applications for Dental
							Implant, Composites and Compounds 2(1) (2020). ## [18] A. Moghanian, A.
							Ghorbanoghli, M. Kazem‐Rostami, A. Pazhouheshgar, E. Salari, M. Saghafi
							Yazdi, T. Alimardani, H. Jahani, F. Sharifian Jazi, M. Tahriri, Novel
							antibacterial Cu/Mg‐substituted 58S‐bioglass: Synthesis,
							characterization and investigation of in vitro bioactivity,
							International Journal of Applied Glass Science (2019) 1-14. ## [19] L.
							Bazli, M. Siavashi, A. Shiravi, A Review of Carbon nanotube/TiO2
							Composite prepared via Sol-Gel method, Journal of Composites and
							Compounds 1(1) (2019) 1-12. ## [20] W.-T. Lin, J.-C. Chen, Y.-C. Hsiao,
							C.-J. Shih, Re-crystallization of silica-based calcium phosphate glass
							prepared by sol–gel technique, Ceramics International 43(16) (2017)
							13388-13393. ## [21] J.R. Jones, Reprint of: Review of bioactive glass:
							From Hench to hybrids, Acta Biomaterialia 23 (2015) S53-S82. ## [22] J.
							Pawlik, M. Widziołek, K. Cholewa-Kowalska, M. Łączka, A.M. Osyczka, New
							sol-gel bioactive glass and titania composites with enhanced
							physico-chemical and biological properties, Journal of Biomedical
							Materials Research Part A 102(7) (2014) 2383-2394. ## [23] J.P. Fan, P.
							Kalia, L. Di Silvio, J. Huang, In vitro response of human osteoblasts to
							multi-step sol–gel derived bioactive glass nanoparticles for bone tissue
							engineering, Materials Science and Engineering: C 36 (2014) 206-214. ##
							[24] R.C. Bielby, I.S. Christodoulou, R.S. Pryce, W.J.P. Radford, L.L.
							Hench, J.M. Polak, Time- and Concentration-Dependent Effects of
							Dissolution Products of 58S Sol–Gel Bioactive Glass on Proliferation and
							Differentiation of Murine and Human Osteoblasts, Tissue Engineering
							10(7-8) (2004) 1018-1026. ## [25] C. Mao, X. Chen, G. Miao, C. Lin,
							Angiogenesis stimulated by novel nanoscale bioactive glasses, Biomedical
							materials 10(2) (2015) 025005.##</REF>
					</REFRENCE>
				</REFRENCES>
			</ARTICLE>
			<ARTICLE>
				<LANGUAGE_ID>1</LANGUAGE_ID>
				<TitleF>-</TitleF>
				<TitleE>Investigation of aluminum oxide coatings created by electrolytic plasma
					method in different potential regimes</TitleE>
				<URL>https://jourcc.com/index.php/jourcc/article/view/jcc232</URL>
				<DOI>10.29252/jcc.2.3.2</DOI>
				<DOR/>
				<ABSTRACTS>
					<ABSTRACT>
						<LANGUAGE_ID>1</LANGUAGE_ID>
						<CONTENT>One of the most important coating methods on aluminum surfaces is
							the electrolytic plasma method. The main objective of the present study
							is to investigate the potential of aluminum oxide coatings created by
							electrolytic plasma method. Aluminum series 2 and the electrolyte of
							sodium silicate, sodium tetraphosphate, sodium aluminate, and potassium
							hydroxide were used. The results showed that the appropriate voltage to
							achieve uniform coating with ideal thickness and morphology is 500 V.
							Adding sodium silicate to the electrolyte solution will create porosity
							and non-adhesion to the substrate. On the other hand, the use of tetra
							sodium pyrophosphate increases the adhesion of the coating by
							penetrating phosphorus into the metal/coating interface. The optimum
							solution for plasma electrolytic oxidation coatings composed of 10, 3,
							and 3 g/l of tetra sodium pyrophosphate, sodium aluminate, and KOH,
							respectively. DC pulsed coating was shown to control the coating process
							and coating uniformity. In addition, the appropriate frequency to apply
							coating was DC pulse potential at 1000 Hz frequency under the 30% duty
							cycle.</CONTENT>
					</ABSTRACT>
					<ABSTRACT>
						<LANGUAGE_ID>0</LANGUAGE_ID>
						<CONTENT>-</CONTENT>
					</ABSTRACT>
				</ABSTRACTS>
				<PAGES>
					<PAGE>
						<FPAGE>115</FPAGE>
						<TPAGE>122</TPAGE>
					</PAGE>
				</PAGES>

				<AUTHORS>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Mahsa</NameE>
						<MidNameE/>
						<FamilyE>Amiri</FamilyE>
						<Organizations>
							<Organization>Material and Metallurgical Engineering Department,
								Amirkabir University of Technology</Organization>
						</Organizations>
						<Countries>
							<Country>Iran</Country>
						</Countries>
						<EMAILS>
							<Email>info@jourcc.com</Email>
						</EMAILS>
					</AUTHOR>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Saman</NameE>
						<MidNameE/>
						<FamilyE>Padervand</FamilyE>
						<Organizations>
							<Organization>Material and Metallurgical Engineering Department,
								Amirkabir University of Technology</Organization>
						</Organizations>
						<Countries>
							<Country>Iran</Country>
						</Countries>
						<EMAILS>
							<Email>info@jourcc.com</Email>
						</EMAILS>
					</AUTHOR>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Vahid</NameE>
						<MidNameE/>
						<FamilyE>Tavakoli Targhi</FamilyE>
						<Organizations>
							<Organization>Material and Metallurgical Engineering Department,
								Amirkabir University of Technology</Organization>
						</Organizations>
						<Countries>
							<Country>Iran</Country>
						</Countries>
						<EMAILS>
							<Email>info@jourcc.com</Email>
						</EMAILS>
					</AUTHOR>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Seyed Mohammad</NameE>
						<MidNameE/>
						<FamilyE>Mousavi khoei</FamilyE>
						<Organizations>
							<Organization>Material and Metallurgical Engineering Department,
								Amirkabir University of Technology</Organization>
						</Organizations>
						<Countries>
							<Country>Iran</Country>
						</Countries>
						<EMAILS>
							<Email>Mmousavi@aut.ac.ir</Email>
						</EMAILS>
					</AUTHOR>
				</AUTHORS>
				<KEYWORDS>
					<KEYWORD>
						<KeyText>Electrolyte plasma method</KeyText>
					</KEYWORD>
					<KEYWORD>
						<KeyText>Aluminum oxide coatings</KeyText>
					</KEYWORD>
					<KEYWORD>
						<KeyText>Potential applied regime</KeyText>
					</KEYWORD>
				</KEYWORDS>
				<REFRENCES>
					<REFRENCE>
						<REF>[1] V.A. Andrei, C. Radulescu, V. Malinovschi, A. Marin, E. Coaca, M.
							Mihalache, C.N. Mihailescu, I.D. Dulama, S. Teodorescu, I.A. Bucurica,
							Aluminum Oxide Ceramic Coatings on 316l Austenitic Steel Obtained by
							Plasma Electrolysis Oxidation Using a Pulsed Unipolar Power Supply,
							Coatings 10(4) (2020) 318. ## [2] T. Iman, G. Ehsan, Production methods
							of CNT-reinforced Al matrix composites: a review, Journal of Composites
							and Compounds 2(2) (2020). ## [3] Z. Kaiqiang, J. Ho Won, L. Quyet Van,
							Production methods of ceramic-reinforced Al-Li matrix composites: A
							review, Journal of Composites and Compounds 2(3) (2020). ## [4] E.H.
							Jazi, R. Esalmi-Farsani, G. Borhani, F.S. Jazi, Synthesis and
							Characterization of In Situ Al-Al13Fe4-Al2O3-TiB2 Nanocomposite Powder
							by Mechanical Alloying and Subsequent Heat Treatment, Synthesis and
							Reactivity in Inorganic, Metal-Organic, and Nano-Metal Chemistry 44(2)
							(2014) 177-184. ## [5] K. Zhang, H.W. Jang, Q. Van Le, Production
							methods of ceramic-reinforced Al-Li matrix composites: A review, Journal
							of Composites and Compounds 2(3) (2020) 77-84. ## [6] M. Fattahi, K.
							Vaferi, M. Vajdi, F. Sadegh Moghanlou, A. Sabahi Namini, M. Shahedi Asl,
							Aluminum nitride as an alternative ceramic for fabrication of
							microchannel heat exchangers: A numerical study, Ceramics International
							46(8, Part B) (2020) 11647-11657. ## [7] B. Nayebi, A. Bahmani, M.S.
							Asl, A. Rasooli, M.G. Kakroudi, M. Shokouhimehr, Characteristics of
							dynamically formed oxide films in aluminum–calcium foamable alloys,
							Journal of Alloys and Compounds 655 (2016) 433-441. ## [8] A. Chlanda,
							P. Oberbek, M. Heljak, E. Kijeńska-Gawrońska, T. Bolek, M. Gloc, Ł.
							John, M. Janeta, M.J. Woźniak, Fabrication, multi-scale characterization
							and in-vitro evaluation of porous hybrid bioactive glass polymer-coated
							scaffolds for bone tissue engineering, Materials Science and
							Engineering: C 94 (2019) 516-523. ## [9] M. Shahedi Asl, B. Nayebi, M.
							Shokouhimehr, TEM characterization of spark plasma sintered
							ZrB2–SiC–graphene nanocomposite, Ceramics International 44(13) (2018)
							15269-15273. ## [10] S.A. Delbari, B. Nayebi, E. Ghasali, M.
							Shokouhimehr, M. Shahedi Asl, Spark plasma sintering of TiN ceramics
							codoped with SiC and CNT, Ceramics International 45(3) (2019) 3207-3216.
							## [11] B. Mohammadpour, Z. Ahmadi, M. Shokouhimehr, M. Shahedi Asl,
							Spark plasma sintering of Al-doped ZrB2–SiC composite, Ceramics
							International 45(4) (2019) 4262-4267. ## [12] V. Egorkin, S. Gnedenkov,
							S. Sinebryukhov, I. Vyaliy, A. Gnedenkov, R. Chizhikov, Increasing
							thickness and protective properties of PEO-coatings on aluminum alloy,
							Surface and coatings Technology 334 (2018) 29-42. ## [13] B. Kasalica,
							M. Petković-Benazzouz, M. Sarvan, I. Belča, B. Maksimović, B.
							Misailović, Z. Popović, Mechanisms of plasma electrolytic oxidation of
							aluminum at the multi-hour timescales, Surface and Coatings Technology
							390 (2020) 125681. ## [14] T. Kikuchi, T. Taniguchi, R.O. Suzuki, S.
							Natsui, Fabrication of a plasma electrolytic oxidation/anodic aluminum
							oxide multi-layer film via one-step anodizing aluminum in ammonium
							carbonate, Thin Solid Films 697 (2020) 137799. ## [15] S. Wang, X. Liu,
							X. Yin, N. Du, Influence of electrolyte components on the microstructure
							and growth mechanism of plasma electrolytic oxidation coatings on 1060
							aluminum alloy, Surface and Coatings Technology 381 (2020) 125214. ##
							[16] N. Angulakshmi, R.B. Dhanalakshmi, M. Kathiresan, Y. Zhou, A.M.
							Stephan, The suppression of lithium dendrites by a triazine-based porous
							organic polymer-laden PEO-based electrolyte and its application for
							all-solid-state lithium batteries, Materials Chemistry Frontiers 4(3)
							(2020) 933-940. ## [17] R. Hussein, D. Northwood, X. Nie, The effect of
							processing parameters and substrate composition on the corrosion
							resistance of plasma electrolytic oxidation (PEO) coated magnesium
							alloys, Surface and Coatings Technology 237 (2013) 357-368. ## [18] B.
							Ghorbanian, S.M.M. Khoie, Formation of vanadium carbide with the plasma
							electrolytic saturation method (PES) and comparison with Thermo Reactive
							diffusion method (TRD), Acta Metallurgica Slovaca 22(2) (2016) 111-119.
							## [19] A. Yerokhin, X. Nie, A. Leyland, A. Matthews, S. Dowey, Plasma
							electrolysis for surface engineering, Surface and coatings technology
							122(2-3) (1999) 73-93. ## [20] B. Ghorbanian, S.M.M. Khoie, M. Rasouli,
							R.J. Doodran, Investigation of the electrolyte effects on formation of
							vanadium carbide via plasma electrolytic saturation method (pes),
							Surface Review and Letters 23(04) (2016) 1650021. ## [21] Y. Gao, B.
							Ghorbanian, H.N. Gargari, W. Gao, Catalytic activity of char produced
							from brown coal for steam-gasification of bitumen oil, Petroleum Science
							and Technology 36(1) (2018) 75-78. ## [22] Y. Gao, B. Ghorbanian, H.N.
							Gargari, W. Gao, Steam gasification of bitumen oil in presence of
							Ni/dolomite catalysts, Petroleum Science and Technology 35(21) (2017)
							2074-2079. ## [23] F. Momeni, B. Ghorbanian, S.M.M. Khoie, S.M.M.
							Nazari, M. Rasouli, Study of Current and Voltage Diagram In The Formed
							Vanadium Carbide Coatings Via Plasma Electrolytic Saturation Method,
							JOURNAL OF MATERIALS 7(11) (2016) 4073-4078. ## [24] V. Dehnavi, B.L.
							Luan, D.W. Shoesmith, X.Y. Liu, S. Rohani, Effect of duty cycle and
							applied current frequency on plasma electrolytic oxidation (PEO) coating
							growth behavior, Surface and Coatings Technology 226 (2013) 100-107. ##
							[25] S. Rahimi, F. SharifianJazi, A. Esmaeilkhanian, M. Moradi, A.H.
							Safi Samghabadi, Effect of SiO2 content on Y-TZP/Al2O3
							ceramic-nanocomposite properties as potential dental applications,
							Ceramics International 46(8, Part A) (2020) 10910-10916. ## [26] M.
							Alizadeh, M.H. Paydar, F. Sharifian Jazi, Structural evaluation and
							mechanical properties of nanostructured Al/B4C composite fabricated by
							ARB process, Composites Part B: Engineering 44(1) (2013) 339-343. ##
							[27] J. Curran, T. Clyne, Thermo-physical properties of plasma
							electrolytic oxide coatings on aluminium, Surface and Coatings
							Technology 199(2-3) (2005) 168-176. ## [28] Y.-J. Oh, J.-I. Mun, J.-H.
							Kim, Effects of alloying elements on microstructure and protective
							properties of Al2O3 coatings formed on aluminum alloy substrates by
							plasma electrolysis, Surface and Coatings Technology 204(1-2) (2009)
							141-148.##</REF>
					</REFRENCE>
				</REFRENCES>
			</ARTICLE>
			<ARTICLE>
				<LANGUAGE_ID>1</LANGUAGE_ID>
				<TitleF>-</TitleF>
				<TitleE>Ni-Cu matrix composite reinforced with CNTs: preparation, characterization,
					wear and corrosion behavior, inhibitory effects</TitleE>
				<URL>https://www.jourcc.com/index.php/jourcc/article/view/jcc233</URL>
				<DOI>10.29252/jcc.2.3.3</DOI>
				<DOR/>
				<ABSTRACTS>
					<ABSTRACT>
						<LANGUAGE_ID>1</LANGUAGE_ID>
						<CONTENT>‎St37 steel has been used in various industries due to its
							abundance and low cost. However the high corrosion rate of the steel in
							acidic environments is one of the limiting factors for its application.
							In this study, Ni-Cu composite coating reinforced with CNTs was applied
							on st37 steel substrate. The extract of Sarang Semut plant was entered
							to the coating as inhibitory particles and the electrochemical behavior
							of the coating was investigated. Hardness, pin-on-disk, and dynamic
							potential polarization tests were performed. Results showed that the
							presence of CNT particles improves the hardness, tribological behavior,
							and electrochemical behavior of the coating. Also, the presence of
							Sarang Semut particles acted as a barrier and protected the surface of
							st37 steel from corrosion. It should be noted that these particles
							affected the kinetics and thermodynamics of corrosion reactions and were
							not involved in the corrosion reactions.</CONTENT>
					</ABSTRACT>
					<ABSTRACT>
						<LANGUAGE_ID>0</LANGUAGE_ID>
						<CONTENT>-</CONTENT>
					</ABSTRACT>
				</ABSTRACTS>
				<PAGES>
					<PAGE>
						<FPAGE>123</FPAGE>
						<TPAGE>128</TPAGE>
					</PAGE>
				</PAGES>

				<AUTHORS>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Morteza</NameE>
						<MidNameE/>
						<FamilyE>Ferdosi Heragh</FamilyE>
						<Organizations>
							<Organization>Faculty of Materials and Metallurgical Engineering, Semnan
								University</Organization>
						</Organizations>
						<Countries>
							<Country>Iran</Country>
						</Countries>
						<EMAILS>
							<Email>info@jourcc.com</Email>
						</EMAILS>
					</AUTHOR>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Sara</NameE>
						<MidNameE/>
						<FamilyE>Eskandarinezhad</FamilyE>
						<Organizations>
							<Organization>Department of Mining and Metallurgical Engineering, Yazd
								University</Organization>
						</Organizations>
						<Countries>
							<Country>Iran</Country>
						</Countries>
						<EMAILS>
							<Email>s.eskandari.nezhad@gmail.com</Email>
						</EMAILS>
					</AUTHOR>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Alireza</NameE>
						<MidNameE/>
						<FamilyE>Dehghan</FamilyE>
						<Organizations>
							<Organization>Department of Research and Development, Applied research
								center of the geological survey of Iran</Organization>
						</Organizations>
						<Countries>
							<Country>Iran</Country>
						</Countries>
						<EMAILS>
							<Email>info@jourcc.com</Email>
						</EMAILS>
					</AUTHOR>
				</AUTHORS>
				<KEYWORDS>
					<KEYWORD>
						<KeyText>St37</KeyText>
					</KEYWORD>
					<KEYWORD>
						<KeyText>Corrosion resistance</KeyText>
					</KEYWORD>
					<KEYWORD>
						<KeyText>CNTs</KeyText>
					</KEYWORD>
					<KEYWORD>
						<KeyText>Ni-Cu composite coating</KeyText>
					</KEYWORD>
				</KEYWORDS>
				<REFRENCES>
					<REFRENCE>
						<REF>[1] N.D. Hassiotis, G.P. Petropoulos, Influence of surface roughness on
							corrosion resistance of turned carbon steel parts, International Journal
							of Machining and Machinability of Materials 1(2) (2006) 202-212. ## [2]
							I. Tajzad, E. Ghasali, Production methods of CNT-reinforced Al matrix
							composites: a review, Journal of Composites and Compounds 2(1) (2020)
							1-9. ## [3] S.-W. Kim, B.-G. Jeon, D.-G. Hahm, M.-K. Kim, Ratcheting
							fatigue failure of a carbon steel pipe tee in a nuclear power plant
							using the deformation angle, Engineering Failure Analysis (2020) 104595.
							## [4] P. Jordan, C. Maharaj, Asset management strategy for HAZ cracking
							caused by sigma-phase and creep embrittlement in 304H stainless steel
							piping, Engineering Failure Analysis 110 (2020) 104452. ## [5] M.
							Ferdosi Heragh, H. Tavakoli, Electrochemical Properties of a New Green
							Corrosion Inhibitor Derived from Prosopis farcta for St37 Steel in 1 M
							Hydrochloric Acid, Metals and Materials International (2019). ## [6]
							A.H. Shahbaz, M. Esmaeilian, R. NasrAzadani, K. Gavanji, The effect of
							MgF2 addition on the mechanical properties of hydroxyapatite synthesized
							via powder metallurgy, Journal of Composites and Compounds 1(1) (2019)
							18-24. ## [7] S.E. Sanni, A.P. Ewetade, M.E. Emetere, O. Agboola, E.
							Okoro, S.J. Olorunshola, T.S. Olugbenga, Enhancing the inhibition
							potential of sodium tungstate towards mitigating the corrosive effect of
							Acidithiobaccillus thiooxidan on X-52 carbon steel, Materials Today
							Communications 19 (2019) 238-251. ## [8] A. Pruna, Advances in carbon
							nanotube technology for corrosion applications, Handbook of Polymer
							Nanocomposites. Processing, Performance and Application, Springer2015,
							pp. 335-359. ## [9] R.S. Erami, M. Amirnasr, S. Meghdadi, M. Talebian,
							H. Farrokhpour, K. Raeissi, Carboxamide derivatives as new corrosion
							inhibitors for mild steel protection in hydrochloric acid solution,
							Corrosion Science 151 (2019) 190-197. ## [10] M. Adabi, A.A. Amadeh,
							Electrodeposition mechanism of Ni–Al composite coating, Transactions of
							Nonferrous Metals Society of China 24(10) (2014) 3189-3195. ## [11] Z.M.
							Al-Rashidy, M. Farag, N.A. Ghany, A. Ibrahim, W.I. Abdel-Fattah,
							Orthopaedic bioactive glass/chitosan composites coated 316L stainless
							steel by green electrophoretic co-deposition, Surface and Coatings
							Technology 334 (2018) 479-490. ## [12] T. Abedi, S.K. Asl, Synthesis of
							a novel functionally graded coatings of Ni-Cr/Al2O3 nanocomposite
							coating by pulse electrodeposition, Materials Research Express 6(5)
							(2019). ## [13] D. Zhang, H. Zhang, S. Zhao, Z. Li, S. Hou,
							Electrochemical impedance spectroscopy evaluation of corrosion
							protection of X65 carbon steel by halloysite nanotube-filled epoxy
							composite coatings in 3.5% NaCl solution, Int. J. Electrochem. Sci 14
							(2019) 4659-4667. ## [14] X. He, R. Song, D. Kong, Microstructure and
							corrosion behaviour of laser-cladding Al-Ni-TiC-CeO2 composite coatings
							on S355 offshore steel, Journal of Alloys and Compounds 770 (2019)
							771-783. ## [15] M.A.U. Rehman, M.A. Munawar, D.W. Schubert, A.R.
							Boccaccini, Electrophoretic deposition of chitosan/gelatin/bioactive
							glass composite coatings on 316L stainless steel: A design of experiment
							study, Surface and Coatings Technology 358 (2019) 976-986. ## [16] Z.
							Abdel Hamid, A.Y. El-Etre, M. Fareed, Performance of Ni–Cu–ZrO2
							nanocomposite coatings fabricated by electrodeposition technique,
							Anti-Corrosion Methods and Materials 64(3) (2017) 315-325. ## [17] M.
							Alizadeh, H. Safaei, Characterization of Ni-Cu matrix, Al2O3 reinforced
							nano-composite coatings prepared by electrodeposition, Applied Surface
							Science 456 (2018) 195-203. ## [18] Z. Hu, X. Jie, G. Lu, Corrosion
							resistance of Pb–Sn composite coatings reinforced by carbon nanotubes,
							Journal of coatings technology and research 7(6) (2010) 809-814. ## [19]
							Y. Orooji, A.a. Alizadeh, E. Ghasali, M.R. Derakhshandeh, M. Alizadeh,
							M.S. Asl, T. Ebadzadeh, Co-reinforcing of mullite-TiN-CNT composites
							with ZrB2 and TiB2 compounds, Ceramics International 45(16) (2019)
							20844-20854. ## [20] A. Agarwal, S.R. Bakshi, D. Lahiri, Carbon
							nanotubes: reinforced metal matrix composites, CRC press2018. ## [21] G.
							Fan, Y. Jiang, Z. Tan, Q. Guo, D.-b. Xiong, Y. Su, R. Lin, L. Hu, Z. Li,
							D. Zhang, Enhanced interfacial bonding and mechanical properties in
							CNT/Al composites fabricated by flake powder metallurgy, Carbon 130
							(2018) 333-339. ## [22] M. Chen, G. Fan, Z. Tan, D. Xiong, Q. Guo, Y.
							Su, J. Zhang, Z. Li, M. Naito, D. Zhang, Design of an efficient flake
							powder metallurgy route to fabricate CNT/6061Al composites, Materials
							and Design 142 (2018) 288-296. ## [23] M. Akbarpour, S. Alipour, M.
							Farvizi, H. Kim, Mechanical, tribological and electrical properties of
							Cu-CNT composites fabricated by flake powder metallurgy method, Archives
							of Civil and Mechanical Engineering 19 (2019) 694-706. ## [24] A.
							Pradityana, Sulistijono, A. Shahab, S. Chyntara, Eco-friendly green
							inhibitor of mild steel in 3, 5% NaCl solution by Sarang Semut
							(Myrmecodia Pendans) extract, AIP Conference Proceedings, AIP, 2014, pp.
							161-164. ## [25] P. Dai, C. Zhang, J. Wen, H. Rao, Q. Wang, Tensile
							properties of electrodeposited nanocrystalline Ni-Cu alloys, Journal of
							Materials Engineering and Performance 25(2) (2016) 594-600. ## [26] I.
							Bakonyi, E. Tóth-Kádár, J. Tóth, T. Becsei, T. Tarnóczi, P. Kamasa,
							Magnetic and electrical transport properties of electrodeposited Ni-Cu
							alloys and multilayers, Journal of Physics: Condensed Matter 11(4)
							(1999) 963. ## [27] U. Sarac, M.C. Baykul, Morphological and
							microstructural properties of two-phase Ni–Cu films electrodeposited at
							different electrolyte temperatures, Journal of alloys and compounds 552
							(2013) 195-201. ## [28] L. Chen, L. Wang, Z. Zeng, T. Xu, Influence of
							pulse frequency on the microstructure and wear resistance of
							electrodeposited Ni–Al2O3 composite coatings, Surface and Coatings
							Technology 201(3) (2006) 599-605. ## [29] L. Wang, Y. Gao, Q. Xue, H.
							Liu, T. Xu, Microstructure and tribological properties of
							electrodeposited Ni–Co alloy deposits, Applied Surface Science 242(3-4)
							(2005) 326-332. ## [30] M. Zamani, A. Amadeh, S.L. Baghal, Effect of Co
							content on electrodeposition mechanism and mechanical properties of
							electrodeposited Ni–Co alloy, Transactions of Nonferrous Metals Society
							of China 26(2) (2016) 484-491. ## [31] L. Reinert, S. Suárez, A.
							Rosenkranz, Tribo-mechanisms of carbon nanotubes: friction and wear
							behavior of CNT-reinforced nickel matrix composites and CNT-coated bulk
							nickel, Lubricants 4(2) (2016) 11. ## [32] A. Laszczyńska, J. Winiarski,
							B. Szczygieł, I. Szczygieł, Electrodeposition and characterization of
							Ni–Mo–ZrO2 composite coatings, Applied Surface Science 369 (2016)
							224-231. ## [33] Q. Feng, T. Li, H. Teng, X. Zhang, Y. Zhang, C. Liu, J.
							Jin, Investigation on the corrosion and oxidation resistance of Ni–Al2O3
							nano-composite coatings prepared by sediment co-deposition, Surface and
							Coatings Technology 202(17) (2008) 4137-4144. ## [34] M. Alizadeh,
							Strengthening mechanisms in particulate Al/B4C composites produced by
							repeated roll bonding process, Journal of Alloys and Compounds 509(5)
							(2011) 2243-2247. ## [35] M. Alishahi, S.M. Monirvaghefi, A. Saatchi,
							S.M. Hosseini, The effect of carbon nanotubes on the corrosion and
							tribological behavior of electroless Ni–P–CNT composite coating, Applied
							Surface Science 258(7) (2012) 2439-2446. ## [36] Z.-q. MENG, X.-b. LI,
							Y.-j. XIONG, Z. Jing, Preparation and tribological performances of
							Ni-P-multi-walled carbon nanotubes composite coatings, Transactions of
							Nonferrous Metals Society of China 22(11) (2012) 2719-2725. ## [37] R.
							Casati, M. Vedani, Metal matrix composites reinforced by
							nano-particles—a review, Metals 4(1) (2014) 65-83. ## [38] Z. Li, X.
							Wang, M. Wang, F. Wang, H. Ge, Preparation and tribological properties
							of the carbon nanotubes–Ni–P composite coating, Tribology international
							39(9) (2006) 953-957. ## [39] X. Chen, C. Chen, H. Xiao, H. Liu, L.
							Zhou, S. Li, G. Zhang, Dry friction and wear characteristics of
							nickel/carbon nanotube electroless composite deposits, Tribology
							international 39(1) (2006) 22-28. ## [40] W. Chen, J. Tu, H. Gan, Z. Xu,
							Q. Wang, J. Lee, Z. Liu, X. Zhang, Electroless preparation and
							tribological properties of Ni-P-Carbon nanotube composite coatings under
							lubricated condition, Surface and Coatings Technology 160(1) (2002)
							68-73. ## [41] A.D. Moghadam, E. Omrani, P.L. Menezes, P.K. Rohatgi,
							Mechanical and tribological properties of self-lubricating metal matrix
							nanocomposites reinforced by carbon nanotubes (CNTs) and graphene–a
							review, Composites Part B: Engineering 77 (2015) 402-420. ## [42] A.
							Barbucci, G. Farne, P. Matteazzi, R. Riccieri, G. Cerisola, Corrosion
							behaviour of nanocrystalline Cu90Ni10 alloy in neutral solution
							containing chlorides, Corrosion Science 41(3) (1998) 463-475. ## [43] H.
							Dhar, R.E. White, G. Burnell, L. Cornwell, R. Griffin, R. Darby,
							Corrosion of Cu and Cu-Ni alloys in 0.5 M NaCl and in synthetic
							seawater, Corrosion 41(6) (1985) 317-323. ## [44] A. Varea, E. Pellicer,
							S. Pané, B.J. Nelson, S. Suriñach, M.D. Baró, J. Sort, Mechanical
							properties and corrosion behaviour of nanostructured Cu-rich CuNi
							electrodeposited films, Int. J. Electrochem. Sci 7(2) (2012) 1288-1302.
							## [45] H.-h. Zhou, Z.-w. Liao, C.-x. Fang, H.-x. Li, F. Bin, X. Song,
							G.-f. Cao, Y.-f. Kuang, Pulse electroplating of Ni-WP coating and its
							anti-corrosion performance, Transactions of Nonferrous Metals Society of
							China 28(1) (2018) 88-95. ## [46] M. Metikoš-Huković, I. Škugor, Z.
							Grubač, R. Babić, Complexities of corrosion behaviour of copper–nickel
							alloys under liquid impingement conditions in saline water,
							Electrochimica acta 55(9) (2010) 3123-3129. ## [47] Q. Li, X. Yang, L.
							Zhang, J. Wang, B. Chen, Corrosion resistance and mechanical properties
							of pulse electrodeposited Ni–TiO2 composite coating for sintered NdFeB
							magnet, Journal of Alloys and Compounds 482(1-2) (2009) 339-344. ## [48]
							H.R. Bakhsheshi‐Rad, X. Chen, A.F. Ismail, M. Aziz, E. Abdolahi, F.
							Mahmoodiyan, Improved antibacterial properties of an Mg‐Zn‐Ca alloy
							coated with chitosan nanofibers incorporating silver sulfadiazine
							multiwall carbon nanotubes for bone implants, Polymers for Advanced
							Technologies 30(5) (2019) 1333-1339. ## [49] L.-Y. Cui, S.-D. Gao, P.-P.
							Li, R.-C. Zeng, F. Zhang, S.-Q. Li, E.-H. Han, Corrosion resistance of a
							self-healing micro-arc oxidation/polymethyltrimethoxysilane composite
							coating on magnesium alloy AZ31, Corrosion Science 118 (2017) 84-95. ##
							[50] S. Mo, L.J. Li, H.Q. Luo, N.B. Li, An example of green copper
							corrosion inhibitors derived from flavor and medicine: vanillin and
							isoniazid, Journal of Molecular Liquids 242 (2017) 822-830. ## [51] M.
							Abdallah, Antibacterial drugs as corrosion inhibitors for corrosion of
							aluminium in hydrochloric solution, Corrosion Science 46(8) (2004)
							1981-1996.##</REF>
					</REFRENCE>
				</REFRENCES>
			</ARTICLE>
			<ARTICLE>
				<LANGUAGE_ID>1</LANGUAGE_ID>
				<TitleF>-</TitleF>
				<TitleE>Corrosion behavior of aluminum oxide coatings created by electrolytic plasma
					method under different potential regimes</TitleE>
				<URL>https://www.jourcc.com/index.php/jourcc/article/view/jcc234</URL>
				<DOI>10.29252/jcc.2.3.4</DOI>
				<DOR/>
				<ABSTRACTS>
					<ABSTRACT>
						<LANGUAGE_ID>1</LANGUAGE_ID>
						<CONTENT>The electrolytic plasma coating is affected by various factors such
							as electrolyte conductivity, voltage, and current. However, there has
							not been much attention to the effect of the current regime. The main
							objective of the present study is to investigate the potential of Al2O3
							coatings deposited by the electrolytic plasma method. Aluminum Series 2
							was used in this study and the electrolyte was composed of sodium
							silicate, sodium tetraphosphate, sodium aluminate and potassium
							hydroxide. The results showed that, in general, according to the
							impedance diagrams, the corrosion resistance of the coated specimens
							greatly increases with the immersion time. Therefore, the unit of
							resistance increased on average to about 10 MHz after 72 hours. In the
							case of pulsed potential application regime, the corrosion behavior of
							the samples in the working cycle of 30% was better than that of 70%,
							which can be related to the thickness of the formed coatings and their
							porosity. This allows the coating to degrade the coating faster by
							increasing the thickness and decreasing the porosity of the aggressive
							chloride ion.</CONTENT>
					</ABSTRACT>
					<ABSTRACT>
						<LANGUAGE_ID>0</LANGUAGE_ID>
						<CONTENT>-</CONTENT>
					</ABSTRACT>
				</ABSTRACTS>
				<PAGES>
					<PAGE>
						<FPAGE>129</FPAGE>
						<TPAGE>137</TPAGE>
					</PAGE>
				</PAGES>

				<AUTHORS>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Mahsa</NameE>
						<MidNameE/>
						<FamilyE>Amiri</FamilyE>
						<Organizations>
							<Organization>Material and Metallurgical Engineering Department,
								Amirkabir University of Technology</Organization>
						</Organizations>
						<Countries>
							<Country>Iran</Country>
						</Countries>
						<EMAILS>
							<Email>info@jourcc.com</Email>
						</EMAILS>
					</AUTHOR>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Vahid</NameE>
						<MidNameE/>
						<FamilyE>Tavakoli Targhi</FamilyE>
						<Organizations>
							<Organization>Material and Metallurgical Engineering Department,
								Amirkabir University of Technology</Organization>
						</Organizations>
						<Countries>
							<Country>Iran</Country>
						</Countries>
						<EMAILS>
							<Email>info@jourcc.com</Email>
						</EMAILS>
					</AUTHOR>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Saman</NameE>
						<MidNameE/>
						<FamilyE>Padervand</FamilyE>
						<Organizations>
							<Organization>Material and Metallurgical Engineering Department,
								Amirkabir University of Technology</Organization>
						</Organizations>
						<Countries>
							<Country>Iran</Country>
						</Countries>
						<EMAILS>
							<Email>info@jourcc.com</Email>
						</EMAILS>
					</AUTHOR>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Seyed Mohammad</NameE>
						<MidNameE/>
						<FamilyE>Mousavi khoei</FamilyE>
						<Organizations>
							<Organization>Material and Metallurgical Engineering Department,
								Amirkabir University of Technology</Organization>
						</Organizations>
						<Countries>
							<Country>Iran</Country>
						</Countries>
						<EMAILS>
							<Email>Mmousavi@aut.ac.ir</Email>
						</EMAILS>
					</AUTHOR>
				</AUTHORS>
				<KEYWORDS>
					<KEYWORD>
						<KeyText>Plasma electrolytic oxidation</KeyText>
					</KEYWORD>
					<KEYWORD>
						<KeyText>Aluminum oxide coatings</KeyText>
					</KEYWORD>
					<KEYWORD>
						<KeyText>Potential regime</KeyText>
					</KEYWORD>
					<KEYWORD>
						<KeyText>Corrosion</KeyText>
					</KEYWORD>
				</KEYWORDS>
				<REFRENCES>
					<REFRENCE>
						<REF>[1] I. Tajzad, E. Ghasali, Production methods of CNT-reinforced Al
							matrix composites: a review, Journal of Composites and Compounds 2(1)
							(2020) 1-9. ## [2] K. Zhang, H.W. Jang, Q. Van Le, Production methods of
							ceramic-reinforced Al-Li matrix composites: A review, Journal of
							Composites and Compounds 2(3) (2020) 77-84. ## [3] F. Sharifianjazi, M.
							Moradi, A. Abouchenari, A.H. Pakseresht, A. Esmaeilkhanian, M.
							Shokouhimehr, M.S. Asl, Effects of Sr and Mg dopants on biological and
							mechanical properties of SiO2–CaO–P2O5 bioactive glass, Ceramics
							International (2020). ## [4] B. Ghorbanian, S.M.M. Khoie, Formation of
							vanadium carbide with the plasma electrolytic saturation method (PES)
							and comparison with Thermo Reactive diffusion method (TRD), Acta
							Metallurgica Slovaca 22(2) (2016) 111-119. ## [5] S. Nasibi, K.
							Alimohammadi, L. Bazli, S. Eskandarinezhad, A. Mohammadi, N. Sheysi,
							TZNT alloy for surgical implant applications: A systematic review,
							Journal of Composites and Compounds 2(3) (2020) 62-68. ## [6] B.
							Kasalica, M. Petković-Benazzouz, M. Sarvan, I. Belča, B. Maksimović, B.
							Misailović, Z. Popović, Mechanisms of plasma electrolytic oxidation of
							aluminum at the multi-hour timescales, Surface and Coatings Technology
							(2020) 125681. ## [7] T. Kikuchi, T. Taniguchi, R.O. Suzuki, S. Natsui,
							Fabrication of a plasma electrolytic oxidation/anodic aluminum oxide
							multi-layer film via one-step anodizing aluminum in ammonium carbonate,
							Thin Solid Films 697 (2020) 137799. ## [8] W. Liu, C. Blawert, M.L.
							Zheludkevich, Y. Lin, M. Talha, Y. Shi, L. Chen, Effects of graphene
							nanosheets on the ceramic coatings formed on Ti6Al4V alloy drill pipe by
							plasma electrolytic oxidation, Journal of Alloys and Compounds 789
							(2019) 996-1007. ## [9] L. Famiyeh, H. Xiaohu, Improving Corrosion
							Resistance and Mechanical Properties of Aluminum and its Alloys via
							Plasma Electrolytic Oxidation (PEO) for Aerospace Applications: A
							Review. ## [10] R. Barik, J. Wharton, R. Wood, K. Stokes, R. Jones,
							Corrosion, erosion and erosion–corrosion performance of plasma
							electrolytic oxidation (PEO) deposited Al2O3 coatings, Surface and
							coatings technology 199(2-3) (2005) 158-167. ## [11] L. Pezzato, M.
							Rigon, A. Martucci, K. Brunelli, M. Dabalà, Plasma Electrolytic
							Oxidation (PEO) as pre-treatment for sol-gel coating on aluminum and
							magnesium alloys, Surface and Coatings Technology 366 (2019) 114-123. ##
							[12] V. Dehnavi, B.L. Luan, D.W. Shoesmith, X.Y. Liu, S. Rohani, Effect
							of duty cycle and applied current frequency on plasma electrolytic
							oxidation (PEO) coating growth behavior, Surface and Coatings Technology
							226 (2013) 100-107. ## [13] S.S. Kamble, A. Gunasekaran, S.A. Gawankar,
							Sustainable Industry 4.0 framework: A systematic literature review
							identifying the current trends and future perspectives, Process Safety
							and Environmental Protection 117 (2018) 408-425. ## [14] J.
							Parameswaranpillai, S.K. Sidhardhan, P. Harikrishnan, J. Pionteck, S.
							Siengchin, A.B. Unni, A. Magueresse, Y. Grohens, N. Hameed, S. Jose,
							Morphology, thermo-mechanical properties and surface hydrophobicity of
							nanostructured epoxy thermosets modified with PEO-PPO-PEO triblock
							copolymer, Polymer Testing 59 (2017) 168-176. ## [15] J. Curran, T.
							Clyne, Thermo-physical properties of plasma electrolytic oxide coatings
							on aluminium, Surface and Coatings Technology 199(2-3) (2005) 168-176.
							## [16] Y.-J. Oh, J.-I. Mun, J.-H. Kim, Effects of alloying elements on
							microstructure and protective properties of Al2O3 coatings formed on
							aluminum alloy substrates by plasma electrolysis, Surface and Coatings
							Technology 204(1-2) (2009) 141-148. ## [17] A. Shirani, T. Joy, A.
							Rogov, M. Lin, A. Yerokhin, J.-E. Mogonye, A. Korenyi-Both, S.M. Aouadi,
							A.A. Voevodin, D. Berman, PEO-Chameleon as a potential protective
							coating on cast aluminum alloys for high-temperature applications,
							Surface and Coatings Technology (2020) 126016. ## [18] J. Guest, S.
							Papavinasam, N.S. Berke, S. Brossia, Corrosion Monitoringand
							Measurement. ## [19] Y. Rao, Q. Wang, D. Oka, C.S. Ramachandran, On the
							PEO treatment of cold sprayed 7075 aluminum alloy and its effects on
							mechanical, corrosion and dry sliding wear performances thereof, Surface
							and Coatings Technology 383 (2020) 125271. ## [20] T. Arunnellaiappan,
							S. Arun, S. Hariprasad, S. Gowtham, B. Ravisankar, N. Rameshbabu,
							Fabrication of corrosion resistant hydrophobic ceramic nanocomposite
							coatings on PEO treated AA7075, Ceramics International 44(1) (2018)
							874-884. ## [21] E. Parfenov, A. Yerokhin, A. Matthews, Impedance
							spectroscopy characterisation of PEO process and coatings on aluminium,
							Thin solid films 516(2-4) (2007) 428-432. ## [22] A. Bahramian, K.
							Raeissi, A. Hakimizad, Characterizing of DC-Plasma Electrolytic
							Oxidation (PEO) Coatings on 7075 Aluminum Alloy. ## [23] K. Khaled,
							Electrochemical investigation and modeling of corrosion inhibition of
							aluminum in molar nitric acid using some sulphur-containing amines,
							Corrosion Science 52(9) (2010) 2905-2916. ## [24] E. Akbari, F. Di
							Franco, P. Ceraolo, K. Raeissi, M. Santamaria, A. Hakimizad,
							Electrochemically-induced TiO2 incorporation for enhancing corrosion and
							tribocorrosion resistance of PEO coating on 7075 Al alloy, Corrosion
							Science 143 (2018) 314-328. ## [25] H.P. Hack, J.R. Scully, Defect area
							determination of organic coated steels in seawater using the breakpoint
							frequency method, Journal of the Electrochemical Society 138(1) (1991)
							33. ## [26] V. Egorkin, S. Gnedenkov, S. Sinebryukhov, I. Vyaliy, A.
							Gnedenkov, R. Chizhikov, Increasing thickness and protective properties
							of PEO-coatings on aluminum alloy, Surface and coatings Technology 334
							(2018) 29-42. ## [27] I.Š. Rončević, Z. Grubač, M. Metikoš-Huković,
							Electrodeposition of hydroxyapatite coating on AZ91D alloy for
							biodegradable implant application, Int. J. Electrochem. Sci 9 (2014)
							5907-5923. ## [28] A. Hakimizad, K. Raeissi, M.A. Golozar, X. Lu, C.
							Blawert, M.L. Zheludkevich, The effect of pulse waveforms on surface
							morphology, composition and corrosion behavior of Al2O3 and Al2O3/TiO2
							nano-composite PEO coatings on 7075 aluminum alloy, Surface and Coatings
							Technology 324 (2017) 208-221. ## [29] G. Paglia, C. Buckley, A. Rohl,
							B. Hunter, R. Hart, J. Hanna, L. Byrne, Tetragonal structure model for
							boehmite-derived γ-alumina, Physical Review B 68(14) (2003)
							144110.</REF>
					</REFRENCE>
				</REFRENCES>
			</ARTICLE>
			<ARTICLE>
				<LANGUAGE_ID>1</LANGUAGE_ID>
				<TitleF>-</TitleF>
				<TitleE>The rechargeable aluminum-ion battery with different composite cathodes: A
					review</TitleE>
				<URL>https://www.jourcc.com/index.php/jourcc/article/view/jcc235</URL>
				<DOI>10.29252/jcc.2.3.5</DOI>
				<DOR/>
				<ABSTRACTS>
					<ABSTRACT>
						<LANGUAGE_ID>1</LANGUAGE_ID>
						<CONTENT>Digital cameras, laptop computers, cellular phones, as well as many
							portable electronic devices require batteries for powering. Based on the
							electrolyte type, electrolytic batteries can be categorized into
							solid-based, liquid-based, and ionic-based batteries. Aluminum ion
							batteries (AIBs) have some promising properties such as low cost, high
							safety, and high specific volumetric capacity. Nevertheless, in order
							for AIBs to be extensively used, developing novel electrode materials
							possessing high energy density is required. This is mainly dependent on
							the cathode materials. However, these cathode materials have some
							drawbacks such as structural decomposition, low battery capacity, low
							discharge voltage, and volume expansion resulting from the intercalation
							of large-sized ions. Therefore, future research might concentrate on the
							investigation of cheaper electrolyte and novel cathode materials for
							enhancement of energy density and working voltage. This review focuses
							on the recent cathodes, in particular, composite cathode materials,
							including graphite, CuS, V2O5, Li3VO4@C, VS4/rGO, and
							Ni3S2/graphene.</CONTENT>
					</ABSTRACT>
					<ABSTRACT>
						<LANGUAGE_ID>0</LANGUAGE_ID>
						<CONTENT>-</CONTENT>
					</ABSTRACT>
				</ABSTRACTS>
				<PAGES>
					<PAGE>
						<FPAGE>138</FPAGE>
						<TPAGE>146</TPAGE>
					</PAGE>
				</PAGES>

				<AUTHORS>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Leyla</NameE>
						<MidNameE/>
						<FamilyE>Saei Fard</FamilyE>
						<Organizations>
							<Organization>Department of Organic and Biochemistry, University of
								Tabriz</Organization>
						</Organizations>
						<Countries>
							<Country>Iran</Country>
						</Countries>
						<EMAILS>
							<Email>leylasaiifard@yahoo.com</Email>
						</EMAILS>
					</AUTHOR>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Naeimeh Sadat</NameE>
						<MidNameE/>
						<FamilyE>Peighambardoust</FamilyE>
						<Organizations>
							<Organization>Koç University Boron and Advanced Materials Applications
								and Research Center (KUBAM)</Organization>
						</Organizations>
						<Countries>
							<Country>Turkey</Country>
						</Countries>
						<EMAILS>
							<Email>info@jourcc.com</Email>
						</EMAILS>
					</AUTHOR>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Ho Won</NameE>
						<MidNameE/>
						<FamilyE>Jang</FamilyE>
						<Organizations>
							<Organization>Department of Materials Science and Engineering, Seoul
								National University</Organization>
						</Organizations>
						<Countries>
							<Country>Republic of Korea</Country>
						</Countries>
						<EMAILS>
							<Email>info@jourcc.com</Email>
						</EMAILS>
					</AUTHOR>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Alireza</NameE>
						<MidNameE/>
						<FamilyE>Dehghan</FamilyE>
						<Organizations>
							<Organization>Department of Research and Development, Applied research
								center of the geological survey of Iran</Organization>
						</Organizations>
						<Countries>
							<Country>Iran</Country>
						</Countries>
						<EMAILS>
							<Email>info@jourcc.com</Email>
						</EMAILS>
					</AUTHOR>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Niloufar</NameE>
						<MidNameE/>
						<FamilyE>Nehzat Khosh Saligheh</FamilyE>
						<Organizations>
							<Organization>Shomal University</Organization>
						</Organizations>
						<Countries>
							<Country>Iran</Country>
						</Countries>
						<EMAILS>
							<Email>info@jourcc.com</Email>
						</EMAILS>
					</AUTHOR>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Marjan</NameE>
						<MidNameE/>
						<FamilyE>Iranpour</FamilyE>
						<Organizations>
							<Organization>Department of Agricultural Machinery Mechanics, Univesity
								of Tehran</Organization>
						</Organizations>
						<Countries>
							<Country>Iran</Country>
						</Countries>
						<EMAILS>
							<Email>info@jourcc.com</Email>
						</EMAILS>
					</AUTHOR>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Mitra</NameE>
						<MidNameE/>
						<FamilyE>Isvand Rajabi</FamilyE>
						<Organizations>
							<Organization>Islamic Azad University, Dezful Branch</Organization>
						</Organizations>
						<Countries>
							<Country>Iran</Country>
						</Countries>
						<EMAILS>
							<Email>info@jourcc.com</Email>
						</EMAILS>
					</AUTHOR>
				</AUTHORS>
				<KEYWORDS>
					<KEYWORD>
						<KeyText>Liquid electrolyte</KeyText>
					</KEYWORD>
					<KEYWORD>
						<KeyText>Solid electrolyte</KeyText>
					</KEYWORD>
					<KEYWORD>
						<KeyText>Ionic electrolyte</KeyText>
					</KEYWORD>
					<KEYWORD>
						<KeyText>Aluminum-ion battery</KeyText>
					</KEYWORD>
					<KEYWORD>
						<KeyText>Composite cathodes</KeyText>
					</KEYWORD>
				</KEYWORDS>
				<REFRENCES>
					<REFRENCE>
						<REF>[1] S. Saadi, B. Nazari, Recent developments and applications of
							nanocomposites in solar cells: a review, Journal of Composites and
							Compounds 1(1) (2019) 48-58. ## [2] J. Shin, Ionic liquids to the rescue
							Overcoming the ionic conductivity limitations of polymer electrolytes,
							Electrochemistry Communications 5(12) (2003) 1016-1020. ## [3] X. Zhang,
							S. Wang, J. Tu, G. Zhang, S. Li, D. Tian, S. Jiao, Flower-like Vanadium
							Suflide/Reduced Graphene Oxide Composite: An Energy Storage Material for
							Aluminum-Ion Batteries, ChemSusChem 11(4) (2018) 709-715. ## [4] T.
							Leisegang, F. Meutzner, M. Zschornak, W. Munchgesang, R. Schmid, T.
							Nestler, R.A. Eremin, A.A. Kabanov, V.A. Blatov, D.C. Meyer, The
							Aluminum-Ion Battery: A Sustainable and Seminal Concept?, Front Chem 7
							(2019) 268. ## [5] A. Kim, Li Intercalation into Carbonaceous Anode
							Materials for LiAlCl4∙3SO2 Electrolyte Based Lithium Ion Battery,
							Hanyang, 2019. ## [6] S. Wang, Z. Yu, J. Tu, J. Wang, D. Tian, Y. Liu,
							S. Jiao, A novel aluminum‐ion battery: Al/AlCl3‐[EMIm]
							Cl/Ni3S2@graphene, Advanced Energy Materials 6(13) (2016) 1600137. ##
							[7] J. Li, C. Ma, M. Chi, C. Liang, N.J. Dudney, Solid Electrolyte: the
							Key for High-Voltage Lithium Batteries, Advanced Energy Materials 5(4)
							(2015). ## [8] Y. Ru, S. Zheng, H. Xue, H. Pang, Potassium cobalt
							hexacyanoferrate nanocubic assemblies for high-performance aqueous
							aluminum ion batteries, Chemical Engineering Journal 382 (2020) 122853.
							## [9] K. Zhang, H.W. Jang, Q. Van Le, Production methods of
							ceramic-reinforced Al-Li matrix composites: A review, Journal of
							Composites and Compounds 2(3) (2020) 76-84. ## [10] I. Tajzad, E.
							Ghasali, Production methods of CNT-reinforced Al matrix composites: a
							review, Journal of Composites and Compounds 2(1) (2020) 1-9. ## [11] J.
							Jiang, H. Li, J. Huang, K. Li, J. Zeng, Y. Yang, J. Li, Y. Wang, J.
							Wang, J. Zhao, Investigation of the Reversible
							Intercalation/Deintercalation of Al into the Novel Li3VO4@C Microsphere
							Composite Cathode Material for Aluminum-Ion Batteries, ACS Appl Mater
							Interfaces 9(34) (2017) 28486-28494. ## [12] S. Wang, S. Jiao, J. Wang,
							H.S. Chen, D. Tian, H. Lei, D.N. Fang, High-Performance Aluminum-Ion
							Battery with CuS@C Microsphere Composite Cathode, ACS Nano 11(1) (2017)
							469-477. ## [13] N.C. Rosero-Navarro, A. Miura, K. Tadanaga, Preparation
							of lithium ion conductive Li6PS5Cl solid electrolyte from solution for
							the fabrication of composite cathode of all-solid-state lithium battery,
							Journal of Sol-Gel Science and Technology 89(1) (2019) 303-309. ## [14]
							L. Larush, V. Borgel, E. Markevich, O. Haik, E. Zinigrad, D. Aurbach, G.
							Semrau, M. Schmidt, On the thermal behavior of model Li–LixCoO2 systems
							containing ionic liquids in standard electrolyte solutions, Journal of
							Power Sources 189(1) (2009) 217-223. ## [15] A. Lewandowski, A.
							Świderska-Mocek, Ionic liquids as electrolytes for Li-ion batteries—An
							overview of electrochemical studies, Journal of Power Sources 194(2)
							(2009) 601-609. ## [16] Y. Zhang, Y. Zhao, K. Eun Sun, P. Chen,
							Development in lithium/sulfur secondary batteries, The Open Materials
							Science Journal 5(1) (2011). ## [17] S.S. Zhang, Liquid electrolyte
							lithium/sulfur battery: fundamental chemistry, problems, and solutions,
							Journal of Power Sources 231 (2013) 153-162. ## [18] R. Rauh, K.
							Abraham, G. Pearson, J. Surprenant, S. Brummer, A lithium/dissolved
							sulfur battery with an organic electrolyte, Journal of the
							Electrochemical Society 126(4) (1979) 523. ## [19] E. Peled, Y.
							Sternberg, A. Gorenshtein, Y. Lavi, Lithium‐sulfur battery: evaluation
							of dioxolane‐based electrolytes, Journal of the Electrochemical Society
							136(6) (1989) 1621. ## [20] S.S. Zhang, J.A. Read, A new direction for
							the performance improvement of rechargeable lithium/sulfur batteries,
							Journal of Power Sources 200 (2012) 77-82. ## [21] Z. Ye, Z. Cao, M.O.
							Lam Chee, P. Dong, P.M. Ajayan, J. Shen, M. Ye, Advances in Zn-ion
							batteries via regulating liquid electrolyte, Energy Storage Materials 32
							(2020) 290-305. ## [22] S. Sarwar, M.-s. Lee, S. Park, T.T. Dao, A.
							Ullah, S. Hong, C.-H. Han, Transformation of a liquid electrolyte to a
							gel inside dye sensitized solar cells for better stability and
							performance, Thin Solid Films 704 (2020) 138024. ## [23] S.S. Zhang, New
							insight into liquid electrolyte of rechargeable lithium/sulfur battery,
							Electrochimica Acta 97 (2013) 226-230. ## [24] H. Yamin, A. Gorenshtein,
							J. Penciner, Y. Sternberg, E. Peled, Lithium sulfur battery:
							oxidation/reduction mechanisms of polysulfides in THF solutions, Journal
							of the Electrochemical Society 135(5) (1988) 1045. ## [25] D.
							Marmorstein, T. Yu, K. Striebel, F. McLarnon, J. Hou, E. Cairns,
							Electrochemical performance of lithium/sulfur cells with three different
							polymer electrolytes, Journal of Power Sources 89(2) (2000) 219-226. ##
							[26] H.-S. Ryu, H.-J. Ahn, K.-W. Kim, J.-H. Ahn, J.-Y. Lee, Discharge
							process of Li/PVdF/S cells at room temperature, Journal of Power Sources
							153(2) (2006) 360-364. ## [27] J. Shin, S. Jung, K. Kim, H. Ahn, J. Ahn,
							Preparation and characterization of plasticized polymer electrolytes
							based on the PVdF-HFP copolymer for lithium/sulfur battery, Journal of
							Materials Science: Materials in Electronics 13(12) (2002) 727-733. ##
							[28] B.H. Jeon, J.H. Yeon, I.J. Chung, Preparation and electrical
							properties of lithium–sulfur-composite polymer batteries, Journal of
							materials processing technology 143 (2003) 93-97. ## [29] B.H. Jeon,
							J.H. Yeon, K.M. Kim, I.J. Chung, Preparation and electrochemical
							properties of lithium–sulfur polymer batteries, Journal of power sources
							109(1) (2002) 89-97. ## [30] J.-W. Choi, J.-K. Kim, G. Cheruvally, J.-H.
							Ahn, H.-J. Ahn, K.-W. Kim, Rechargeable lithium/sulfur battery with
							suitable mixed liquid electrolytes, Electrochimica Acta 52(5) (2007)
							2075-2082. ## [31] E. Peled, A. Gorenshtein, M. Segal, Y. Sternberg,
							Rechargeable lithium sulfur battery, Journal of Power Sources 26(3-4)
							(1989) 269-271. ## [32] H. Ryu, H. Ahn, K. Kim, J. Ahn, J.-Y. Lee, E.
							Cairns, Self-discharge of lithium–sulfur cells using stainless-steel
							current-collectors, Journal of Power Sources 140(2) (2005) 365-369. ##
							[33] D.-R. Chang, S.-H. Lee, S.-W. Kim, H.-T. Kim, Binary electrolyte
							based on tetra (ethylene glycol) dimethyl ether and 1, 3-dioxolane for
							lithium–sulfur battery, Journal of Power Sources 112(2) (2002) 452-460.
							## [34] S.-E. Cheon, K.-S. Ko, J.-H. Cho, S.-W. Kim, E.-Y. Chin, H.-T.
							Kim, Rechargeable lithium sulfur battery: I. Structural change of sulfur
							cathode during discharge and charge, Journal of the Electrochemical
							Society 150(6) (2003) A796. ## [35] H.-S. Ryu, H.-J. Ahn, K.-W. Kim,
							J.-H. Ahn, K.-K. Cho, T.-H. Nam, J.-U. Kim, G.-B. Cho, Discharge
							behavior of lithium/sulfur cell with TEGDME based electrolyte at low
							temperature, Journal of Power Sources 163(1) (2006) 201-206. ## [36] J.
							Wang, Y. Wang, X. He, J. Ren, C. Jiang, C. Wan, Electrochemical
							characteristics of sulfur composite cathode materials in rechargeable
							lithium batteries, Journal of power sources 138(1-2) (2004) 271-273. ##
							[37] J. Wang, L. Liu, Z. Ling, J. Yang, C. Wan, C. Jiang, Polymer
							lithium cells with sulfur composites as cathode materials,
							Electrochimica Acta 48(13) (2003) 1861-1867. ## [38] H. Yang, F. Wu, Y.
							Bai, C. Wu, Toward better electrode/electrolyte interfaces in the
							ionic-liquid-based rechargeable aluminum batteries, Journal of Energy
							Chemistry 45 (2020) 98-102. ## [39] X. Wang, Z. Shang, A. Yang, Q.
							Zhang, F. Cheng, D. Jia, J. Chen, Combining quinone cathode and ionic
							liquid electrolyte for organic sodium-ion batteries, Chem 5(2) (2019)
							364-375. ## [40] X. Ke, Y. Wang, L. Dai, C. Yuan, Cell failures of
							all-solid-state lithium metal batteries with inorganic solid
							electrolytes: Lithium dendrites, Energy Storage Materials (2020). ##
							[41] X. Wang, J. Sun, C. Feng, X. Wang, M. Xu, J. Sun, N. Zhang, J. Ma,
							Q. Wang, C. Zong, G. Cui, Lithium bis(oxalate)borate crosslinked polymer
							electrolytes for high-performance lithium batteries, Journal of Energy
							Chemistry 55 (2021) 228-235. ## [42] X. Zhang, W. Zhou, M. Zhang, Z.
							Yang, W. Huang, Superior performance for lithium-ion battery with
							organic cathode and ionic liquid electrolyte, Journal of Energy
							Chemistry 52 (2021) 28-32. ## [43] Z. Zhang, J. Zhang, H. Jia, L. Peng,
							T. An, J. Xie, Enhancing ionic conductivity of solid electrolyte by
							lithium substitution in halogenated Li-Argyrodite, Journal of Power
							Sources 450 (2020) 227601. ## [44] M.A.K.L. Dissanayake, T. Liyanage, T.
							Jaseetharan, G.K.R. Senadeera, B.S. Dassanayake, Effect of PbS quantum
							dot-doped polysulfide nanofiber gel polymer electrolyte on efficiency
							enhancement in CdS quantum dot-sensitized TiO2 solar cells,
							Electrochimica Acta 347 (2020) 136311. ## [45] A. Gupta, A. Bhargav,
							J.-P. Jones, R.V. Bugga, A. Manthiram, Influence of Lithium Polysulfide
							Clustering on the Kinetics of Electrochemical Conversion in
							Lithium–Sulfur Batteries, Chemistry of Materials 32(5) (2020) 2070-2077.
							## [46] Z. Liu, V.S. Manikandan, A. Chen, Recent advances in
							nanomaterial-based electrochemical sensing of nitric oxide and nitrite
							for biomedical and food research, Current Opinion in Electrochemistry 16
							(2019) 127-133. ## [47] S.-e. Sheng, L. Sheng, L. Wang, N. Piao, X. He,
							Thickness variation of lithium metal anode with cycling, Journal of
							Power Sources 476 (2020) 228749. ## [48] L. Kong, L. Yin, F. Xu, J.
							Bian, H. Yuan, Z. Lu, Y. Zhao, Electrolyte solvation chemistry for
							lithium–sulfur batteries with electrolyte-lean conditions, Journal of
							Energy Chemistry 55 (2021) 80-91. ## [49] R. Weber, M. Genovese, A.
							Louli, S. Hames, C. Martin, I.G. Hill, J. Dahn, Long cycle life and
							dendrite-free lithium morphology in anode-free lithium pouch cells
							enabled by a dual-salt liquid electrolyte, Nature Energy 4(8) (2019)
							683-689. ## [50] H. Xia, C. Li, H. Chen, Green preparation of CuI
							particles in dielectric barrier discharge for colorimetric determination
							of trace mercury in comparison with atomic fluorescence spectrometric
							determination, Microchemical Journal 146 (2019) 1169-1172. ## [51] H.
							Zhuo, X. Wang, A. Tang, Z. Liu, S. Gamboa, P. Sebastian, The preparation
							of NaV1−xCrxPO4F cathode materials for sodium-ion battery, Journal of
							power sources 160(1) (2006) 698-703. ## [52] R. Alcántara, J.M.
							Jiménez-Mateos, P. Lavela, J.L. Tirado, Carbon black: a promising
							electrode material for sodium-ion batteries, Electrochemistry
							Communications 3(11) (2001) 639-642. ## [53] S. Komaba, C. Takei, T.
							Nakayama, A. Ogata, N. Yabuuchi, Electrochemical intercalation activity
							of layered NaCrO2 vs. LiCrO2, Electrochemistry Communications 12(3)
							(2010) 355-358. ## [54] P. Moreau, D. Guyomard, J. Gaubicher, F.
							Boucher, Structure and stability of sodium intercalated phases in
							olivine FePO4, Chemistry of Materials 22(14) (2010) 4126-4128. ## [55]
							K.O. Oyedotun, T.M. Masikhwa, S. Lindberg, A. Matic, P. Johansson, N.
							Manyala, Comparison of ionic liquid electrolyte to aqueous electrolytes
							on carbon nanofibres supercapacitor electrode derived from
							oxygen-functionalized graphene, Chemical Engineering Journal 375 (2019)
							121906. ## [56] H. Ryu, T. Kim, K. Kim, J.-H. Ahn, T. Nam, G. Wang,
							H.-J. Ahn, Discharge reaction mechanism of room-temperature
							sodium–sulfur battery with tetra ethylene glycol dimethyl ether liquid
							electrolyte, Journal of Power Sources 196(11) (2011) 5186-5190. ## [57]
							R. Pathak, K. Chen, A. Gurung, K.M. Reza, B. Bahrami, J. Pokharel, A.
							Baniya, W. He, F. Wu, Y. Zhou, Fluorinated hybrid
							solid-electrolyte-interphase for dendrite-free lithium deposition,
							Nature communications 11(1) (2020) 1-10. ## [58] Y. Liu, J. Liu, Q. Sun,
							D. Wang, K.R. Adair, J. Liang, C. Zhang, L. Zhang, S. Lu, H. Huang,
							Insight into the microstructure and ionic conductivity of cold sintered
							NASICON solid electrolyte for solid-state batteries, ACS applied
							materials and interfaces 11(31) (2019) 27890-27896. ## [59] Z. Chang, Y.
							Qiao, H. Deng, H. Yang, P. He, H. Zhou, A Liquid Electrolyte with
							De-Solvated Lithium Ions for Lithium-Metal Battery, Joule 4(8) (2020)
							1776-1789. ## [60] Y. Deng, X. Zhu, N. Chen, C. Feng, H. Wang, P. Kuang,
							W. Hu, Review on electrochemical system for landfill leachate treatment:
							Performance, mechanism, application, shortcoming, and improvement
							scheme, Science of The Total Environment 745 (2020) 140768. ## [61] A.
							Sakuda, A. Hayashi, M. Tatsumisago, Sulfide solid electrolyte with
							favorable mechanical property for all-solid-state lithium battery, Sci
							Rep 3 (2013) 2261. ## [62] A.L. Santhosha, L. Medenbach, T.
							Palaniselvam, P. Adelhelm, Sodium-Storage Behavior of Exfoliated MoS2 as
							an Electrode Material for Solid-State Batteries with Na3PS4 as the Solid
							Electrolyte, The Journal of Physical Chemistry C 124(19) (2020)
							10298-10305. ## [63] T. Le Varlet, O. Schmidt, A. Gambhir, S. Few, I.
							Staffell, Comparative life cycle assessment of lithium-ion battery
							chemistries for residential storage, Journal of Energy Storage 28 (2020)
							101230. ## [64] R. Yazami, Y.F. Reynier, Mechanism of self-discharge in
							graphite–lithium anode, Electrochimica Acta 47(8) (2002) 1217-1223. ##
							[65] P. Novák, J.-C. Panitz, F. Joho, M. Lanz, R. Imhof, M. Coluccia,
							Advanced in situ methods for the characterization of practical
							electrodes in lithium-ion batteries, Journal of power sources 90(1)
							(2000) 52-58. ## [66] N. Ogihara, Y. Igarashi, A. Kamakura, K. Naoi, Y.
							Kusachi, K. Utsugi, Disordered carbon negative electrode for
							electrochemical capacitors and high-rate batteries, Electrochimica acta
							52(4) (2006) 1713-1720. ## [67] F. Ding, Y. Liu, X. Hu, 1,3-dioxolane
							pretreatment to improve the interfacial characteristics of a lithium
							anode, Rare Metals 25(4) (2006) 297-302. ## [68] P. Verma, P. Maire, P.
							Novák, A review of the features and analyses of the solid electrolyte
							interphase in Li-ion batteries, Electrochimica Acta 55(22) (2010)
							6332-6341. ## [69] K.-H. Lee, D.B. Ahn, J.-H. Kim, J.-W. Lee, S.-Y. Lee,
							Printed Built-In Power Sources, Matter 2(2) (2020) 345-359. ## [70] D.J.
							Suh, C. Kwak, J.-H. Kim, S.M. Kwon, T.-J. Park, Removal of carbon
							monoxide from hydrogen-rich fuels by selective low-temperature oxidation
							over base metal added platinum catalysts, Journal of Power Sources
							142(1) (2005) 70-74. ## [71] A. Sakuda, A. Hayashi, T. Ohtomo, S. Hama,
							M. Tatsumisago, LiCoO2 electrode particles coated with Li2S–P2S5 solid
							electrolyte for all-solid-state batteries, Electrochemical and Solid
							State Letters 13(6) (2010) A73. ## [72] X. Wang, Y. Qian, L. Wang, H.
							Yang, H. Li, Y. Zhao, T. Liu, Sulfurized polyacrylonitrile cathodes with
							high compatibility in both ether and carbonate electrolytes for
							ultrastable lithium–sulfur batteries, Advanced Functional Materials
							29(39) (2019) 1902929. ## [73] X. Judez, M. Martinez-Ibañez, A.
							Santiago, M. Armand, H. Zhang, C. Li, Quasi-solid-state electrolytes for
							lithium sulfur batteries: Advances and perspectives, Journal of Power
							Sources 438 (2019) 226985. ## [74] S. Wang, K.V. Kravchyk, A.N.
							Filippin, R. Widmer, A.N. Tiwari, S. Buecheler, M.I. Bodnarchuk, M.V.
							Kovalenko, Overcoming the High-Voltage Limitations of Li-Ion Batteries
							Using a Titanium Nitride Current Collector, ACS Applied Energy Materials
							2(2) (2019) 974-978. ## [75] D. Hayashi, K. Suzuki, S. Hori, Y. Yamada,
							M. Hirayama, R. Kanno, Synthesis of Li10GeP2S12-type lithium superionic
							conductors under Ar gas flow, Journal of Power Sources 473 (2020)
							228524. ## [76] L.X. Yuan, J.K. Feng, X.P. Ai, Y.L. Cao, S.L. Chen, H.X.
							Yang, Improved dischargeability and reversibility of sulfur cathode in a
							novel ionic liquid electrolyte, Electrochemistry Communications 8(4)
							(2006) 610-614. ## [77] M. Batteries, CA Vincent and B, Scrosati Wiley,
							New York (1997) 198-242. ## [78] M. Diaw, A. Chagnes, B. Carré, P.
							Willmann, D. Lemordant, Mixed ionic liquid as electrolyte for lithium
							batteries, Journal of Power Sources 146(1-2) (2005) 682-684. ## [79] C.
							Niu, J. Liu, G. Chen, C. Liu, T. Qian, J. Zhang, B. Cao, W. Shang, Y.
							Chen, J. Han, Anion-regulated solid polymer electrolyte enhances the
							stable deposition of lithium ion for lithium metal batteries, Journal of
							Power Sources 417 (2019) 70-75. ## [80] J.-M. Tarascon, M. Armand,
							Issues and challenges facing rechargeable lithium batteries, Materials
							for sustainable energy: a collection of peer-reviewed research and
							review articles from Nature Publishing Group, World Scientific2011, pp.
							171-179. ## [81] ElectroChem integrates fuel cell technology in India,
							South Asia, Fuel Cells Bulletin 2007(8) (2007) 7. ## [82] G. Angajala,
							R. Subashini, V. Aruna, Microwave assisted amberlite-IRA-402 (OH) ion
							exchange resin catalyzed synthesis of new benzoxazole scaffolds derived
							from antiinflammatory drugs aceclofenac and mefenamic acid as potential
							therapeutic agents for inflammation, Journal of Molecular Structure 1200
							(2020) 127092. ## [83] L. Auzel, Y. Ali, C. Monini, J.M. Létang, E.
							Testa, M. Beuve, L. Maigne, 35 Simulation of micro-nanodosimetry spectra
							and free radicals with Geant4-DNA, LQD, PHYCHEML, CHEM for ion beams,
							Physica Medica 68 (2019) 21-22. ## [84] P. Vikas, I. Sudhakar, Dilkush,
							G. MohanaRao, B. Srinivas, Aging behaviour of hot deformed AA7075
							aluminium alloy, Materials Today: Proceedings (2020). ## [85] M.
							Alizadeh, M. Paydar, F.S. Jazi, Structural evaluation and mechanical
							properties of nanostructured Al/B4C composite fabricated by ARB process,
							Composites Part B: Engineering 44(1) (2013) 339-343. ## [86] E.H. Jazi,
							R. Esalmi-Farsani, G. Borhani, F.S. Jazi, Synthesis and Characterization
							of In Situ Al-Al13Fe4-Al2O3-TiB2 Nanocomposite Powder by Mechanical
							Alloying and Subsequent Heat Treatment, Synthesis and Reactivity in
							Inorganic, Metal-Organic, and Nano-Metal Chemistry 44(2) (2014) 177-184.
							## [87] K. Parveen, U. Rafique, M. Javed Akhtar, M. Ashokkumar,
							Sonochemical synthesis of aluminium and aluminium hybrids for
							remediation of toxic metals, Ultrasonics Sonochemistry 70 (2021) 105299.
							## [88] H. Dohle, J. Mergel, D. Stolten, Heat and power management of a
							direct-methanol-fuel-cell (DMFC) system, Journal of Power Sources 111(2)
							(2002) 268-282. ## [89] M. Tamski, J.P. Ansermet, C. Roussel,
							Stabilization of p-GaAs electrode surfaces in organic solvent by
							bi-phenyl rings for spin dependent electron transfer studies, Journal of
							Photochemistry and Photobiology A: Chemistry (2020) 112853. ## [90] A.
							Fernández-Guillamón, E. Gómez-Lázaro, E. Muljadi, Á. Molina-García,
							Power systems with high renewable energy sources: A review of inertia
							and frequency control strategies over time, Renewable and Sustainable
							Energy Reviews 115 (2019) 109369. ## [91] N.R. Avery, K.J. Black,
							Kinetic analysis of capacity fade in lithium/coke half-cells, Journal of
							Power Sources 68(2) (1997) 191-194. ## [92] K.G.Y. Beaudelaire, B.
							Zhuang, J.T. Aladejana, D. Li, X. Hou, Y. Xie, Influence of Mesoporous
							Inorganic Al–B–P Amphiprotic Surfactant Material Resistances of Wood
							against Brown and White-Rot Fungi (Part 1), Coatings 10(2) (2020) 108.
							## [93] S. Abedini, N. Parvin, P. Ashtari, F. Jazi, Microstructure,
							strength and CO2 separation characteristics of α-alumina supported
							γ-alumina thin film membrane, Advances in Applied Ceramics 112(1) (2013)
							17-22. ## [94] H. Sun, W. Wang, Z. Yu, Y. Yuan, S. Wang, S. Jiao, A new
							aluminium-ion battery with high voltage, high safety and low cost,
							Chemical Communications 51(59) (2015) 11892-11895. ## [95] N.S. Hudak,
							Chloroaluminate-doped conducting polymers as positive electrodes in
							rechargeable aluminum batteries, The Journal of Physical Chemistry C
							118(10) (2014) 5203-5215. ## [96] J.V. Rani, V. Kanakaiah, T. Dadmal,
							M.S. Rao, S. Bhavanarushi, Fluorinated natural graphite cathode for
							rechargeable ionic liquid based aluminum–ion battery, Journal of The
							Electrochemical Society 160(10) (2013) A1781. ## [97] S. Liu, J. Hu, N.
							Yan, G. Pan, G. Li, X. Gao, Aluminum storage behavior of anatase TiO2
							nanotube arrays in aqueous solution for aluminum ion batteries, Energy
							and Environmental Science 5(12) (2012) 9743-9746. ## [98] L. Bazli, M.
							Siavashi, A. Shiravi, A Review of Carbon nanotube/TiO2 Composite
							prepared via Sol-Gel method, Journal of Composites and Compounds 1(1)
							(2019) 1-12. ## [99] N. Jayaprakash, S. Das, L. Archer, The rechargeable
							aluminum-ion battery, Chemical Communications 47(47) (2011) 12610-12612.
							## [100] S. Liu, G. Pan, G. Li, X. Gao, Copper hexacyanoferrate
							nanoparticles as cathode material for aqueous Al-ion batteries, Journal
							of Materials Chemistry A 3(3) (2015) 959-962. ## [101] L.D. Reed, E.
							Menke, The roles of V2O5 and stainless steel in rechargeable Al–ion
							batteries, Journal of the Electrochemical Society 160(6) (2013) A915. ##
							[102] W. Wang, B. Jiang, W. Xiong, H. Sun, Z. Lin, L. Hu, J. Tu, J. Hou,
							H. Zhu, S. Jiao, A new cathode material for super-valent battery based
							on aluminium ion intercalation and deintercalation, Scientific reports
							3(1) (2013) 1-6. ## [103] S. Wang, Z. Yu, J. Tu, J. Wang, D. Tian, Y.
							Liu, S. Jiao, A Novel Aluminum-Ion Battery:
							Al/AlCl3-[EMIm]Cl/Ni3S2@Graphene, Advanced Energy Materials 6(13)
							(2016). ## [104] Y. Liu, Q. Sun, W. Li, K.R. Adair, J. Li, X. Sun, A
							comprehensive review on recent progress in aluminum–air batteries, Green
							Energy and Environment 2(3) (2017) 246-277. ## [105] Q. Li, N.J.
							Bjerrum, Aluminum as anode for energy storage and conversion: a review,
							Journal of Power Sources 110(1) (2002) 1-10. ## [106] R.N. Mutlu, I.
							Kucukkara, A.M. Gizir, Hydrogen generation by electrolysis under
							subcritical water condition and the effect of aluminium anode,
							International Journal of Hydrogen Energy 45(23) (2020) 12641-12652. ##
							[107] B. Craig, T. Schoetz, A. Cruden, C. Ponce de Leon, Review of
							current progress in non-aqueous aluminium batteries, Renewable and
							Sustainable Energy Reviews 133 (2020) 110100. ## [108] A. Holland, R.
							Mckerracher, A. Cruden, R. Wills, An aluminium battery operating with an
							aqueous electrolyte, Journal of Applied Electrochemistry 48(3) (2018)
							243-250. ## [109] J. Li, J. Qiao, K. Lian, Hydroxide ion conducting
							polymer electrolytes and their applications in solid supercapacitors: a
							review, Energy Storage Materials 24 (2020) 6-21. ## [110] K.M. Barcelos,
							K.S.G.C. Oliveira, L.A.M. Ruotolo, Insights on the role of interparticle
							porosity and electrode thickness on capacitive deionization performance
							for desalination, Desalination 492 (2020) 114594. ## [111] K.L. Ng, T.
							Dong, J. Anawati, G. Azimi, High‐Performance Aluminum Ion Battery Using
							Cost‐Effective AlCl3‐Trimethylamine Hydrochloride Ionic Liquid
							Electrolyte, Advanced Sustainable Systems (2020) 2000074. ## [112] L.
							Wei, J. Tao, Y. Yang, X. Fan, X. Ran, J. Li, Y. Lin, Z. Huang, Surface
							sulfidization of spinel LiNi0.5Mn1.5O4 cathode material for enhanced
							electrochemical performance in lithium-ion batteries, Chemical
							Engineering Journal 384 (2020) 123268. ## [113] J. Zhong, Z. Yang, Y.
							Yu, Y. Liu, J. Li, F. Kang, Surface substitution of polyanion to improve
							structure stability and electrochemical properties of lithium-rich
							layered cathode oxides, Applied Surface Science 512 (2020) 145741. ##
							[114] Y.-C. Yin, Q. Wang, J.-T. Yang, F. Li, G. Zhang, C.-H. Jiang,
							H.-S. Mo, J.-S. Yao, K.-H. Wang, F. Zhou, Metal chloride perovskite thin
							film based interfacial layer for shielding lithium metal from liquid
							electrolyte, Nature communications 11(1) (2020) 1-9. ## [115] J.
							Schnell, T. Günther, T. Knoche, C. Vieider, L. Köhler, A. Just, M.
							Keller, S. Passerini, G. Reinhart, All-solid-state lithium-ion and
							lithium metal batteries – paving the way to large-scale production,
							Journal of Power Sources 382 (2018) 160-175. ## [116] J. Wei, W. Chen,
							D. Chen, K. Yang, An amorphous carbon-graphite composite cathode for
							long cycle life rechargeable aluminum ion batteries, Journal of
							Materials Science and Technology 34(6) (2018) 983-989. ## [117] K. Zhao,
							X. Shi, Y. Zhao, H. Wei, Q. Sun, T. Huang, X. Zhang, Y. Wang,
							Preparation and immunological effectiveness of a swine influenza DNA
							vaccine encapsulated in chitosan nanoparticles, Vaccine 29(47) (2011)
							8549-8556. ## [118] J. Shin, K. Kim, H. Ahn, J. Ahn, Electrochemical
							properties and interfacial stability of (PEO) 10LiCF3SO3–TinO2n−1
							composite polymer electrolytes for lithium/sulfur battery, Materials
							Science and Engineering: B 95(2) (2002) 148-156. ## [119] D.C. Kim, H.J.
							Shim, W. Lee, J.H. Koo, D.H. Kim, Material‐Based Approaches for the
							Fabrication of Stretchable Electronics, Advanced Materials 32(15) (2020)
							1902743. ## [120] Y.M. Lee, N.-S. Choi, J.H. Park, J.-K. Park,
							Electrochemical performance of lithium/sulfur batteries with protected
							Li anodes, Journal of Power Sources 119 (2003) 964-972. ## [121] S.
							Fang, D. Bresser, S. Passerini, Transition Metal Oxide Anodes for
							Electrochemical Energy Storage in Lithium‐and Sodium‐Ion Batteries,
							Advanced Energy Materials 10(1) (2020) 1902485. ## [122] A. Rafique,
							M.A. Ahmad, I. Shakir, A. Ali, G. Abbas, M.S. Javed, M.A. Khan, R. Raza,
							Multioxide phase-based nanocomposite electrolyte (M@ SDC where M=
							Zn2+/Ba2+/La3+/Zr2+/Al3+) materials, Ceramics International 46(5) (2020)
							6882-6888. ## [123] W. Guan, L. Wang, H. Lei, J. Tu, S. Jiao, Sb2Se3
							nanorods with N-doped reduced graphene oxide hybrids as high-capacity
							positive electrode materials for rechargeable aluminum batteries,
							Nanoscale 11(35) (2019) 16437-16444. ## [124] Y. Zhang, B. Zhang, J. Li,
							J. Liu, X. Huo, F. Kang, SnSe nano-particles as advanced positive
							electrode materials for rechargeable aluminum-ion batteries, Chemical
							Engineering Journal 403 (2021) 126377. ## [125] K. Subramanyan, Y.-S.
							Lee, V. Aravindan, Impact of carbonate-based electrolytes on the
							electrochemical activity of carbon-coated Na3V2(PO4)2F3 cathode in
							full-cell assembly with hard carbon anode, Journal of Colloid and
							Interface Science 582 (2021) 51-59. ## [126] X. Ke, Y. Wang, G. Ren, C.
							Yuan, Towards rational mechanical design of inorganic solid electrolytes
							for all-solid-state lithium ion batteries, Energy Storage Materials 26
							(2020) 313-324. ## [127] Q. Zhao, F.K. Butt, Z. Guo, L. Wang, Y. Zhu, X.
							Xu, X. Ma, C. Cao, High-voltage P2-type manganese oxide cathode induced
							by titanium gradient modification for sodium ion batteries, Chemical
							Engineering Journal 403 (2021) 126308. ## [128] J. Jiang, H. Li, J.
							Huang, K. Li, J. Zeng, Y. Yang, J. Li, Y. Wang, J. Wang, J. Zhao,
							Investigation of the reversible intercalation/deintercalation of Al into
							the novel Li3VO4@ C microsphere composite cathode material for
							aluminum-ion batteries, ACS applied materials and interfaces 9(34)
							(2017) 28486-28494. ## [129] S. Wang, S. Jiao, J. Wang, H.-S. Chen, D.
							Tian, H. Lei, D.-N. Fang, High-performance aluminum-ion battery with
							CuS@ C microsphere composite cathode, ACS nano 11(1) (2017) 469-477. ##
							[130] Y.-Q. Shen, F.-L. Zeng, X.-Y. Zhou, A.-b. Wang, W.-k. Wang, N.-Y.
							Yuan, J.-N. Ding, A novel permselective organo-polysulfides/PVDF gel
							polymer electrolyte enables stable lithium anode for lithium–sulfur
							batteries, Journal of Energy Chemistry 48 (2020) 267-276. ## [131] D.-R.
							Chang, S.-H. Lee, S.-W. Kim, H.-T. Kim, Binary electrolyte based on
							tetra(ethylene glycol) dimethyl ether and 1,3-dioxolane for
							lithium–sulfur battery, Journal of Power Sources 112(2) (2002) 452-460.
							## [132] J. Zhou, X. Zhou, Y. Sun, X. Shen, T. Qian, C. Yan, Insight
							into the reaction mechanism of sulfur chains adjustable polymer cathode
							for high-loading lithium-organosulfur batteries, Journal of Energy
							Chemistry (2020). ## [133] D.K. Rajak, D.D. Pagar, R. Kumar, C.I.
							Pruncu, Recent progress of reinforcement materials: A comprehensive
							overview of composite materials, Journal of Materials Research and
							Technology 8(6) (2019) 6354-6374.</REF>
					</REFRENCE>
				</REFRENCES>
			</ARTICLE>
			<ARTICLE>
				<LANGUAGE_ID>1</LANGUAGE_ID>
				<TitleF>-</TitleF>
				<TitleE>A review on development and application of self-healing thermal barrier
					composite coatings</TitleE>
				<URL>https://www.jourcc.com/index.php/jourcc/article/view/jcc236</URL>
				<DOI>10.29252/jcc.2.3.6</DOI>
				<DOR/>
				<ABSTRACTS>
					<ABSTRACT>
						<LANGUAGE_ID>1</LANGUAGE_ID>
						<CONTENT>To improve the hot section metallic parts durability in advanced
							gas-turbine operating in power generation and aircraft, thermal barrier
							coating (TBCs) are extensively utilized to increase their lifetime. The
							reason for applying coatings on these components is the improvement of
							their physical properties, mechanical properties, and outer look. The
							self-repairing ability of materials is very promising due to expanding
							the service time of materials and it is also beneficial in terms of
							human safety and financial aspects. In this review article, structure,
							properties, limitations, and the modification approaches of TBCs were
							studied. In addition, self-healing agents for TBCs including SiC, MoSi2,
							TiC were introduced, which release their oxide by reaction with air and
							O2 that are able to heal the pores/cracks in the coatings. In this
							regard, their coating methods, mechanism, and applications in TBCs were
							reviewed.</CONTENT>
					</ABSTRACT>
					<ABSTRACT>
						<LANGUAGE_ID>0</LANGUAGE_ID>
						<CONTENT>-</CONTENT>
					</ABSTRACT>
				</ABSTRACTS>
				<PAGES>
					<PAGE>
						<FPAGE>147</FPAGE>
						<TPAGE>154</TPAGE>
					</PAGE>
				</PAGES>

				<AUTHORS>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Aliasghar</NameE>
						<MidNameE/>
						<FamilyE>Abuchenari</FamilyE>
						<Organizations>
							<Organization>Department of Materials Engineering, Shahid Bahonar
								University</Organization>
						</Organizations>
						<Countries>
							<Country>Iran</Country>
						</Countries>
						<EMAILS>
							<Email>info@jourcc.com</Email>
						</EMAILS>
					</AUTHOR>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Hadi</NameE>
						<MidNameE/>
						<FamilyE>Ghazanfari</FamilyE>
						<Organizations>
							<Organization>Department of Mining, Metallurgical and Materials
								Engineering, Université Laval</Organization>
						</Organizations>
						<Countries>
							<Country>Canada</Country>
						</Countries>
						<EMAILS>
							<Email>hadi.ghazanfari.1@ulaval.ca</Email>
						</EMAILS>
					</AUTHOR>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Mostafa</NameE>
						<MidNameE/>
						<FamilyE>Siavashi</FamilyE>
						<Organizations>
							<Organization>Faculty of Engineering, Christian-Albrechts-University
								Kiel</Organization>
						</Organizations>
						<Countries>
							<Country>Germany</Country>
						</Countries>
						<EMAILS>
							<Email>info@jourcc.com</Email>
						</EMAILS>
					</AUTHOR>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Maryam</NameE>
						<MidNameE/>
						<FamilyE>Sabetzadeh</FamilyE>
						<Organizations>
							<Organization>Chemical Engineering Department, Isfahan University of
								Technology</Organization>
						</Organizations>
						<Countries>
							<Country>Iran</Country>
						</Countries>
						<EMAILS>
							<Email>info@jourcc.com</Email>
						</EMAILS>
					</AUTHOR>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Sajad</NameE>
						<MidNameE/>
						<FamilyE>Talebi</FamilyE>
						<Organizations>
							<Organization>Department of Materials and Metallurgy, University of
								Arak</Organization>
						</Organizations>
						<Countries>
							<Country>Iran</Country>
						</Countries>
						<EMAILS>
							<Email>info@jourcc.com</Email>
						</EMAILS>
					</AUTHOR>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Zahra</NameE>
						<MidNameE/>
						<FamilyE>Karami Chemeh</FamilyE>
						<Organizations>
							<Organization>Department of textile Engineering, Amirkabir University of
								Technology</Organization>
						</Organizations>
						<Countries>
							<Country>Iran</Country>
						</Countries>
						<EMAILS>
							<Email>info@jourcc.com</Email>
						</EMAILS>
					</AUTHOR>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Ata</NameE>
						<MidNameE/>
						<FamilyE>Jamavari</FamilyE>
						<Organizations>
							<Organization>Department of Material Science and Engineering, University
								of Science and Technology</Organization>
						</Organizations>
						<Countries>
							<Country>Iran</Country>
						</Countries>
						<EMAILS>
							<Email>info@jourcc.com</Email>
						</EMAILS>
					</AUTHOR>
				</AUTHORS>
				<KEYWORDS>
					<KEYWORD>
						<KeyText>Thermal barrier coating (TBC)</KeyText>
					</KEYWORD>
					<KEYWORD>
						<KeyText>TBC lifetime</KeyText>
					</KEYWORD>
					<KEYWORD>
						<KeyText>TBC modifcation</KeyText>
					</KEYWORD>
					<KEYWORD>
						<KeyText>Self-healing composite</KeyText>
					</KEYWORD>
				</KEYWORDS>
				<REFRENCES>
					<REFRENCE>
						<REF>[1] B. Zhou, S. Yang, C. Wang, X. Hu, W. Song, J. Cai, Q. Xu, N. Sang,
							The characterization of free radical reaction in coal low-temperature
							oxidation with different oxygen concentration, Fuel 262 (2020) 116524.
							## [2] I. Tajzad, E. Ghasali, Production methods of CNT-reinforced Al
							matrix composites: a review, Journal of Composites and Compounds 2(1)
							(2020) 1-9. ## [3] J. Daraei, Production and characterization of PCL
							(Polycaprolactone) coated TCP/nanoBG composite scaffolds by sponge foam
							method for orthopedic applications, Journal of Composites and Compounds
							2(1) (2020) 45-50. ## [4] Z. Goudarzi, A. Ijadi, A. Bakhtiari, S.
							Eskandarinezhad, N. Azizabadi, M.A. Jazi, Sr-doped bioactive glasses for
							biological applications, Journal of Composites and Compounds 2(3) (2020)
							105-109. ## [5] H. Ullah, K.A. M Azizli, Z.B. Man, M.B.C. Ismail, M.I.
							Khan, The Potential of Microencapsulated Self-healing Materials for
							Microcracks Recovery in Self-healing Composite Systems: A Review,
							Polymer Reviews 56(3) (2016) 429-485. ## [6] S.O. Omid, Z. Goudarzi,
							L.M. Kangarshahi, A. Mokhtarzade, F. Bahrami, Self-expanding stents
							based on shape memory alloys and shape memory polymers, Journal of
							Composites and Compounds 2(3) (2020) 92-98. ## [7] M. Arefian, M.
							Hojjati, I. Tajzad, A. Mokhtarzade, M. Mazhar, A. Jamavari, A review of
							Polyvinyl alcohol/Carboxiy methyl cellulose (PVA/CMC) composites for
							various applications, Journal of Composites and Compounds 2(3) (2020)
							69-76. ## [8] F. Nozahic, D. Monceau, C. Estournès, Thermal cycling and
							reactivity of a MoSi2/ZrO2 composite designed for self-healing thermal
							barrier coatings, Materials and Design 94 (2016) 444-448. ## [9] Z.
							Derelioglu, S. Ponnusami, S. Turteltaub, S. Van der Zwaag, W. Sloof,
							Healing particles in self-healing thermal barrier coatings, (2013). ##
							[10] S. Nasibi, K. Alimohammadi, L. Bazli, S. Eskandarinezhad, A.
							Mohammadi, N. Sheysi, TZNT alloy for surgical implant applications: A
							systematic review, Journal of Composites and Compounds 2(3) (2020)
							62-68. ## [11] M.D. Hager, Self‐healing materials, Handbook of Solid
							State Chemistry (2017) 201-225. ## [12] K. Zhang, H.W. Jang, Q. Van Le,
							Production methods of ceramic-reinforced Al-Li matrix composites: A
							review, Journal of Composites and Compounds 2(3) (2020) 77-84. ## [13]
							L.-Y. Yu, R.-L. Li, H.-L. Wu, S.-F. Zhang, M.-W. Chai, X.-X. Shen, M.
							Hong, H. Lin, Selective Removal of Cu2+ Ion in Aqueous Solution by Poly
							(Acrylic Acid/Acrylamide) Hydrogel, Chinese Journal of Analytical
							Chemistry 48(8) (2020) e20098-e20106. ## [14] C. Chen, S. Chen, Z. Guo,
							W. Hu, Z. Chen, J. Wang, J. Hu, J. Guo, L. Yang, Highly efficient
							self-healing materials with excellent shape memory and unprecedented
							mechanical properties, Journal of Materials Chemistry A (2020). ## [15]
							Z.-Y. Wei, B. Cheng, J. Wang, M.-J. Liu, H.-N. Cai, Extend the thermal
							cyclic lifetime of La2Zr2O7/YSZ DCL TBCs by reducing modulus design on a
							toughening ceramic surface, Surface and Coatings Technology 374 (2019)
							134-143. ## [16] H. Xia, C. Li, H. Chen, Green preparation of CuI
							particles in dielectric barrier discharge for colorimetric determination
							of trace mercury in comparison with atomic fluorescence spectrometric
							determination, Microchemical Journal 146 (2019) 1169-1172. ## [17] A.L.
							Carabat, M.J. Meijerink, J.C. Brouwer, E.M. Kelder, J.R. van Ommen, S.
							van der Zwaag, W.G. Sloof, Protecting the MoSi2 healing particles for
							thermal barrier coatings using a sol-gel produced Al2O3 coating, Journal
							of the European Ceramic Society 38(7) (2018) 2728-2734. ## [18] M.
							Belmonte, Advanced Ceramic Materials for High Temperature Applications,
							Advanced Engineering Materials 8(8) (2006) 693-703. ## [19] F.
							Cernuschi, P. Bison, A. Moscatelli, Microstructural characterization of
							porous thermal barrier coatings by laser flash technique, Acta
							Materialia 57(12) (2009) 3460-3471. ## [20] M. Dietrich, V. Verlotski,
							R. Vassen, D. Stöver, Metal‐Glass Based Composites for Novel
							TBC‐Systems, Materialwissenschaft und Werkstofftechnik: Materials
							Science and Engineering Technology 32(8) (2001) 669-672. ## [21] T.
							Ouyang, X. Fang, Y. Zhang, D. Liu, Y. Wang, S. Feng, T. Zhou, S. Cai, J.
							Suo, Enhancement of high temperature oxidation resistance and spallation
							resistance of SiC-self-healing thermal barrier coatings, Surface and
							Coatings Technology 286 (2016) 365-375. ## [22] C. Yu, H. Liu, C. Jiang,
							Z. Bao, S. Zhu, F. Wang, Modification of NiCoCrAlY with Pt: Part II.
							Application in TBC with pure metastable tetragonal (t′) phase YSZ and
							thermal cycling behavior, Journal of materials science and technology
							35(3) (2019) 350-359. ## [23] G. Pulci, J. Tirillò, F. Marra, F.
							Sarasini, A. Bellucci, T. Valente, C. Bartuli, High temperature
							oxidation of MCrAlY coatings modified by Al2O3 PVD overlay, Surface and
							Coatings Technology 268 (2015) 198-204. ## [24] K.M. Doleker, Y.
							Ozgurluk, A.C. Karaoglanli, Isothermal oxidation and thermal cyclic
							behaviors of YSZ and double-layered YSZ/La2Zr2O7 thermal barrier
							coatings (TBCs), Surface and Coatings Technology 351 (2018) 78-88. ##
							[25] M. Mohammadi, A. Kobayashi, S. Javadpour, S. Jahromi, Evaluation of
							hot corrosion behaviors of Al2O3-YSZ composite TBC on gradient MCrAlY
							coatings in the presence of Na2SO4-NaVO3 salt, Vacuum 167 (2019)
							547-553. ## [26] S. Mahade, D. Zhou, N. Curry, N. Markocsan, P. Nylén,
							R. Vaßen, Tailored microstructures of gadolinium zirconate/YSZ
							multi-layered thermal barrier coatings produced by suspension plasma
							spray: Durability and erosion testing, Journal of Materials Processing
							Technology 264 (2019) 283-294. ## [27] M. Bahamirian, S. Hadavi, M.
							Farvizi, A. Keyvani, M. Rahimipour, Thermal Durability of
							YSZ/Nanostructured Gd2Zr2O7 TBC Undergoing Thermal Cycling, Oxidation of
							Metals 92(5-6) (2019) 401-421. ## [28] J. Wang, J. Sun, Q. Jing, B. Liu,
							H. Zhang, Y. Yongsheng, J. Yuan, S. Dong, X. Zhou, X. Cao, Phase
							stability and thermo-physical properties of ZrO2-CeO2-TiO2 ceramics for
							thermal barrier coatings, Journal of the European Ceramic Society 38(7)
							(2018) 2841-2850. ## [29] N. Ejaz, L. Ali, A. Ahmad, M. Mansoor, M.M.
							Asim, A. Rauf, K. Mehmood, Thermo-Physical Properties Measurement of
							Advanced TBC Materials with Pyrochlore and Perovskite Structures, Key
							Engineering Materials, Trans Tech Publ, 2018, pp. 236-244. ## [30] A.A.
							Abubakar, A.F.M. Arif, S.S. Akhtar, Evolution of internal cracks and
							residual stress during deposition of TBC, Ceramics International (2020).
							## [31] A. Ghoshal, M. Murugan, M.J. Walock, A. Nieto, L. Bravo, B.
							Barnett, M. Pepi, C. Hoffmeister Mock, J. Swab, S. Hirsch, Sandphobic
							coatings and surface modification of hot section components of next
							generation VTOL engines: current and future research efforts, 2018 Joint
							Propulsion Conference, 2018, p. 4831. ## [32] O.P. Golim, N. Prastomo,
							H. Izzudin, S. Hastuty, R. Sundawa, E. Sugiarti, K.A.Z. Thosin,
							Synthesis of alumina ceramic encapsulation for self-healing materials on
							thermal barrier coating, Journal of Physics: Conference Series 985
							(2018) 012036. ## [33] L. Lim, S. Meguid, Modeling and characterisation
							of depletion of aluminium in bond coat and growth of mixed oxides in
							thermal barrier coatings, International Journal of Mechanics and
							Materials in Design (2019) 1-17. ## [34] A.H. Pakseresht, Production,
							Properties, and Applications of High Temperature Coatings, IGI
							Global2018. ## [35] J. Jiang, L. Jiang, Z. Cai, W. Wang, X. Zhao, Y.
							Liu, Z. Cao, Numerical stress analysis of the TBC-film cooling system
							under operating conditions considering the effects of thermal gradient
							and TGO growth, Surface and Coatings Technology 357 (2019) 433-444. ##
							[36] R. Takahashi, J. Assis, F.P. Neto, D. Reis, Heat treatment for TGO
							growth on NiCrAlY for TBC application, Materials Research Express 6(12)
							(2020) 126442. ## [37] X. Zhang, K. Zhou, M. Liu, C. Deng, C. Deng, J.
							Mao, Z. Deng, Mechanisms governing the thermal shock and tensile
							fracture of PS-PVD 7YSZ TBC, Ceramics International 44(4) (2018)
							3973-3980. ## [38] J. Kulczyk-Malecka, X. Zhang, J. Carr, F. Nozahic, C.
							Estournès, D. Monceau, A.L. Carabat, W.G. Sloof, S. van der Zwaag, P.J.
							Withers, P. Xiao, Thermo – mechanical properties of SPS produced
							self-healing thermal barrier coatings containing pure and alloyed MoSi2
							particles, Journal of the European Ceramic Society 38(12) (2018)
							4268-4275. ## [39] J. Mitrić, J. Križan, J. Trajić, G. Križan, M.
							Romčević, N. Paunović, B. Vasić, N. Romčević, Structural properties of
							Eu3+ doped Gd2Zr2O7 nanopowders: Far-infrared spectroscopy, Optical
							Materials 75 (2018) 662-665. ## [40] G. Moskal, A. Jasik, M.
							Mikuśkiewicz, S. Jucha, Thermal resistance determination of Sm2Zr2O7 +
							8YSZ composite type of TBC, Applied Surface Science 515 (2020) 145998.
							## [41] M. Gupta, N. Markocsan, X.-H. Li, R.L. Peng, Improving the
							lifetime of suspension plasma sprayed thermal barrier coatings, Surface
							and Coatings Technology 332 (2017) 550-559. ## [42] Y. Fukushima, M.
							Arai, K. Ito, T. Suidzu, Fusion and TBC Penetration Characteristics of
							Volcanic Ash Collected from Active Volcano, Journal of Thermal Spray
							Technology (2020) 1-15. ## [43] S. Budinovskii, D. Chubarov, P. Matveev,
							A. Smirnov, Deposition and Properties of the Ceramic TBC Layer Prepared
							by Magnetron Sputtering, Russian Metallurgy (Metally) 2019(12) (2019)
							1280-1284. ## [44] X. Cao, R. Vassen, W. Fischer, F. Tietz, W. Jungen,
							D. Stöver, Lanthanum–Cerium Oxide as a Thermal Barrier-Coating Material
							for High-Temperature Applications, Advanced Materials 15(17) (2003)
							1438-1442. ## [45] H. Zhang, J. Zeng, J. Yuan, P. Liang, X. Zhou, S.
							Chen, S. Duo, S. Dong, J. Jiang, L. Deng, Spray power-governed
							microstructure and composition, and their effects on properties of
							lanthanum-cerium-tantalum-oxide thermal barrier coating, Ceramics
							International (2020). ## [46] Y. Bai, W. Fan, K. Liu, Y. Kang, Y. Gao,
							F. Ma, Gradient La2Ce2O7/YSZ thermal barrier coatings tailored by
							synchronous dual powder feeding system, Materials Letters 219 (2018)
							55-58. ## [47] R. Vaßen, M.O. Jarligo, T. Steinke, D.E. Mack, D. Stöver,
							Overview on advanced thermal barrier coatings, Surface and Coatings
							Technology 205(4) (2010) 938-942. ## [48] G. Moskal, Microstructure and
							thermal properties of Sm. ## [49] K.M. Doleker, Y. Ozgurluk, H. Ahlatci,
							A.C. Karaoglanli, Evaluation of oxidation and thermal cyclic behavior of
							YSZ, Gd2Zr2O7 and YSZ/Gd2Zr2O7 TBCs, Surface and Coatings Technology 371
							(2019) 262-275. ## [50] R. Ianoş, P. Barvinschi, Solution combustion
							synthesis of calcium zirconate, CaZrO3, powders, Journal of solid state
							chemistry 183(3) (2010) 491-496. ## [51] K. Neufuss, J. Dubsky, P.
							Rohan, B. Kolman, P. Chraska, L.-M. Berger, R. Zieris, S. Thiele, M.
							Nebelung, Structure and properties of CaZrO3 coatings prepared by WSP
							and APS spraying, ITSC 2003: International Thermal Spray Conference
							2003: Advancing the Science and Applying the Technology, 2003, pp.
							1541-1546. ## [52] M. Pollet, S. Marinel, G. Desgardin, CaZrO3, a
							Ni-co-sinterable dielectric material for base metal-multilayer ceramic
							capacitor applications, Journal of the European Ceramic Society 24(1)
							(2004) 119-127. ## [53] G. Di Girolamo, F. Marra, M. Schioppa, C. Blasi,
							G. Pulci, T. Valente, Evolution of microstructural and mechanical
							properties of lanthanum zirconate thermal barrier coatings at high
							temperature, Surface and Coatings Technology 268 (2015) 298-302. ## [54]
							L.A. Noveed Ejaz*, Akhlaq Ahmad, Muhammad Mansoor, Muhammad Muneeb Asim,
							Abdul Rauf, Khalid Mehmood, Thermo-Physical Properties Measurement of
							Advanced TBC Materials with Pyrochlore and Perovskite Structures, 778
							(2018). ## [55] Z. Yang, P. Zhang, W. Pan, Y. Han, M. Huang, H. Chen, Q.
							Gong, C. Wan, Thermal and oxygen transport properties of complex
							pyrochlore RE2InTaO7 for thermal barrier coating applications, Journal
							of the European Ceramic Society (2020). ## [56] H. Xu, H. Guo, Thermal
							barrier coatings, Elsevier2011. ## [57] H. Lau, Influence of yttria on
							the cyclic lifetime of YSZ TBC deposited on EB-PVD NiCoCrAlY bondcoats
							and its contribution to a modified TBC adhesion mechanism, Surface and
							Coatings Technology 235 (2013) 121-126. ## [58] S. Nouri, S. Sahmani, M.
							Asayesh, M. Aghdam, Improvement of high-temperature oxidation resistance
							of γ-TiAl intermetallic alloy by YSZ-NiCoCrAlY coating using APS
							process, Materials Research Express 6(12) (2019) 126541. ## [59] J. Shi,
							T. Zhang, B. Sun, B. Wang, X. Zhang, L. Song, Isothermal oxidation and
							TGO growth behavior of NiCoCrAlY-YSZ thermal barrier coatings on a
							Ni-based superalloy, Journal of Alloys and Compounds 844 (2020) 156093.
							## [60] M. Peters, C. Leyens, U. Schulz, W.A. Kaysser, EB‐PVD thermal
							barrier coatings for aeroengines and gas turbines, Advanced engineering
							materials 3(4) (2001) 193-204. ## [61] L.B. Chen, Yttria-stabilized
							zirconia thermal barrier coatings-a review, Surface Review and Letters
							13(05) (2006) 535-544. ## [62] B.R. Lawn, N.P. Padture, H. Cait, F.
							Guiberteau, Making ceramics" ductile", Science 263(5150) (1994)
							1114-1116. ## [63] A.H. Pakseresht, A.H. Javadi, M. Bahrami, F.
							Khodabakhshi, A. Simchi, Spark plasma sintering of a multilayer thermal
							barrier coating on Inconel 738 superalloy: Microstructural development
							and hot corrosion behavior, Ceramics International 42(2, Part A) (2016)
							2770-2779. ## [64] F. Nozahic, C. Estournès, A.L. Carabat, W.G. Sloof,
							S. van der Zwaag, D. Monceau, Self-healing thermal barrier coating
							systems fabricated by spark plasma sintering, Materials and Design 143
							(2018) 204-213. ## [65] S.-J. Park, M.-K. Seo, T.-J. Ma, D.-R. Lee,
							Effect of chemical treatment of Kevlar fibers on mechanical interfacial
							properties of composites, Journal of colloid and interface science
							252(1) (2002) 249-255. ## [66] A.H. Pakseresht, A.H. Javadi, E. Ghasali,
							A. Shahbazkhan, S. Shakhesi, Evaluation of hot corrosion behavior of
							plasma sprayed thermal barrier coatings with graded intermediate layer
							and double ceramic top layer, Surface and Coatings Technology 288 (2016)
							36-45. ## [67] N.P. Padture, M. Gell, E.H. Jordan, Thermal barrier
							coatings for gas-turbine engine applications, Science 296(5566) (2002)
							280-284. ## [68] A. Aygun, A.L. Vasiliev, N.P. Padture, X. Ma, Novel
							thermal barrier coatings that are resistant to high-temperature attack
							by glassy deposits, Acta Materialia 55(20) (2007) 6734-6745. ## [69] B.
							Ercan, K.J. Bowman, R.W. Trice, H. Wang, W. Porter, Effect of initial
							powder morphology on thermal and mechanical properties of stand-alone
							plasma-sprayed 7 wt.% Y2O3–ZrO2 coatings, Materials Science and
							Engineering: A 435 (2006) 212-220. ## [70] L. Xie, D. Chen, E.H. Jordan,
							A. Ozturk, F. Wu, X. Ma, B.M. Cetegen, M. Gell, Formation of vertical
							cracks in solution-precursor plasma-sprayed thermal barrier coatings,
							Surface and Coatings Technology 201(3-4) (2006) 1058-1064. ## [71] G.
							Shanmugavelayutham, A. Kobayashi, Mechanical properties and oxidation
							behaviour of plasma sprayed functionally graded zirconia–alumina thermal
							barrier coatings, Materials chemistry and physics 103(2-3) (2007)
							283-289. ## [72] B.-K. Jang, H. Matsubara, Influence of porosity on
							thermophysical properties of nano-porous zirconia coatings grown by
							electron beam-physical vapor deposition, Scripta materialia 54(9) (2006)
							1655-1659. ## [73] R. Lima, B. Marple, Nanostructured YSZ thermal
							barrier coatings engineered to counteract sintering effects, Materials
							Science and Engineering: A 485(1-2) (2008) 182-193. ## [74] H. Chen, X.
							Zhou, C. Ding, Investigation of the thermomechanical properties of a
							plasma-sprayed nanostructured zirconia coating, Journal of the European
							Ceramic Society 23(9) (2003) 1449-1455. ## [75] T. Ouyang, J. Wu, M.
							Yasir, T. Zhou, X. Fang, Y. Wang, D. Liu, J. Suo, Effect of TiC
							self-healing coatings on the cyclic oxidation resistance and lifetime of
							thermal barrier coatings, Journal of Alloys and Compounds 656 (2016)
							992-1003. ## [76] W.G. Sloof, Self healing in coatings at high
							temperatures, Self healing materials, Springer2007, pp. 309-321. ## [77]
							C. Wang, K. Li, X. Shi, J. Sun, Q. He, C. Huo, Self-healing YSZ-La-Mo-Si
							heterogeneous coating fabricated by plasma spraying to protect
							carbon/carbon composites from oxidation, Composites Part B: Engineering
							125 (2017) 181-194. ## [78] S.T. Nguyen, T. Nakayama, M. Takeda, N.N.
							Hieu, T. Takahashi, Development of Yttrium Titanate/Nickel
							Nanocomposites with Self Crack-Healing Ability and Potential Application
							as Thermal Barrier Coating Material, MATERIALS TRANSACTIONS (2020)
							MT-MN2019006. ## [79] Z. Derelioglu, A.L. Carabat, G.M. Song, S.v.d.
							Zwaag, W.G. Sloof, On the use of B-alloyed MoSi2 particles as crack
							healing agents in yttria stabilized zirconia thermal barrier coatings,
							Journal of the European Ceramic Society 35(16) (2015) 4507-4511. ## [80]
							H.E. Eaton, G.D. Linsey, E.Y. Sun, K.L. More, J.B. Kimmel, J.R. Price,
							N. Miriyala, EBC protection of SiC/SiC composites in the gas turbine
							combustion environment: continuing evaluation and refurbishment
							considerations, Turbo Expo: Power for Land, Sea, and Air, American
							Society of Mechanical Engineers, 2001, p. V004T02A010. ## [81] S.C.
							Singhal, Advances in solid oxide fuel cell technology, Solid state
							ionics 135(1-4) (2000) 305-313. ## [82] M.J. Meijerink, Coating of MoSi2
							healing particles for self-healing thermal barrier coatings, Chemical
							Engineering Materials Science and Engineering (2015). ## [83] R. Dutton,
							R. Wheeler, K. Ravichandran, K. An, Effect of heat treatment on the
							thermal conductivity of plasma-sprayed thermal barrier coatings, Journal
							of Thermal Spray Technology 9(2) (2000) 204-209. ## [84] S. Maria Jose,
							C.T. Mathew, J. K.Thomas, Fabrication of Dysprosium doped Y2O3 infrared
							transparent ceramic materials by a microwave sintering technique,
							Materials Today: Proceedings 24 (2020) 2383-2393. ## [85] M.
							Pavić-Čolić, Multi-velocity and multi-temperature model of the mixture
							of polyatomic gases issuing from kinetic theory, Physics Letters A
							383(24) (2019) 2829-2835. ## [86] N. Avci, I. Cimieri, P.F. Smet, D.
							Poelman, Stability improvement of moisture sensitive CaS: Eu2+
							micro-particles by coating with sol–gel alumina, Optical Materials 33(7)
							(2011) 1032-1035. ## [87] J.J. Gibson, Y. Yi, S.J. Birks, Watershed,
							climate, and stable isotope data (oxygen-18 and deuterium) for 50 boreal
							lakes in the oil sands region, northeastern Alberta, Canada, 2002–2017,
							Data in Brief 29 (2020) 105308. ## [88] P. Benda, A. Kalendová,
							Anticorrosion Properties of Pigments based on Ferrite Coated Zinc
							Particles, Physics Procedia 44 (2013) 185-194. ## [89] S. Rabadzhiyska,
							L. Kolaklieva, V. Chitanov, T. Cholakova, R. Kakanakov, N. Dimcheva, K.
							Balashev, Mechanical, wear and corrosion behavior of CrN/TiN multilayer
							coatings deposited by low temperature unbalanced magnetron sputtering
							for biomedical applications, Materials Today: Proceedings 5(8, Part 2)
							(2018) 16012-16021. ## [90] L.W. Martin, Y.H. Chu, R. Ramesh, Advances
							in the growth and characterization of magnetic, ferroelectric, and
							multiferroic oxide thin films, Materials Science and Engineering: R:
							Reports 68(4) (2010) 89-133. ## [91] R. Mateos, G. Baeza, B. Sarriá, L.
							Bravo, Improved LC-MSn characterization of hydroxycinnamic acid
							derivatives and flavonols in different commercial mate (Ilex
							paraguariensis) brands. Quantification of polyphenols, methylxanthines,
							and antioxidant activity, Food Chemistry 241 (2018) 232-241. ## [92] M.
							Tomczyk, A. Mahajan, A. Tkach, P.M. Vilarinho, Interface-based reduced
							coercivity and leakage currents of BiFeO3 thin films: A comparative
							study, Materials and Design 160 (2018) 1322-1334. ## [93] S.
							Bhattacharya, K. Mo, Z. Mei, D. Seidman, B. Stepnik, M.J. Pellin, A.M.
							Yacout, Improving stability of ALD ZrN thin film coatings over U-Mo
							dispersion fuel, Applied Surface Science (2020) 147378. ## [94] L. Chen,
							Yttria-stabilized zirconia thermal barrier coatings—a review, Surface
							Review and Letters 13(05) (2006) 535-544. ## [95] F. Yao, K. Ando, M.C.
							Chu, S. Sato, Static and cyclic fatigue behaviour of crack-healed
							Si3N4/SiC composite ceramics, Journal of the European Ceramic Society
							21(7) (2001) 991-997. ## [96] K. Takahashi, M. Yokouchi, S.-K. Lee, K.
							Ando, Crack-Healing Behavior of Al2O3 Toughened by SiC Whiskers, Journal
							of the American Ceramic Society 86(12) (2003) 2143-2147. ## [97] M. Chu,
							S. Sato, Y. Kobayashi, K. Ando, Damage healing and strengthening
							behaviour in intelligent mullite/SiC ceramics, Fatigue and Fracture of
							Engineering Materials and Structures 18(9) (1995) 1019-1029. ## [98] W.
							Sloof, S. Turteltaub, A. Carabat, Z. Derelioglu, S. Ponnusami, G. Song,
							219 Crack healing in yttria stabilized zirconia thermal barrier
							coatings, Self Healing Materials: Pioneering Research in the Netherlands
							(2015) 219. ## [99] M.E. Smith, Recent progress in solid-state NMR of
							low-γ nuclei, Annual Reports on NMR Spectroscopy, Academic Press2001,
							pp. 121-175. ## [100] S.C. Singhal, Advances in solid oxide fuel cell
							technology, Solid State Ionics 135(1) (2000) 305-313. ## [101] X. Fan,
							W. Huang, X. Zhou, B. Zou, Preparation and characterization of
							NiAl–TiC–TiB2 intermetallic matrix composite coatings by atmospheric
							plasma spraying of SHS powders, Ceramics International (2020). ## [102]
							A.H. Heuer, Oxygen and aluminum diffusion in α-Al2O3: How much do we
							really understand?, Journal of the European Ceramic Society 28(7) (2008)
							1495-1507. ## [103] Y. Oishi, W.D. Kingery, Self‐Diffusion of Oxygen in
							Single Crystal and Polycrystalline Aluminum Oxide, The Journal of
							Chemical Physics 33(2) (1960) 480-486. ## [104] M. MUNRO, Evaluated
							material properties for a sintered alpha‐alumina, Journal of the
							American Ceramic Society 80(8) (1997) 1919-1928. ## [105] S. Xie, C.
							Song, Z. Yu, S. Liu, F. Lapostolle, D. Klein, C. Deng, M. Liu, H. Liao,
							Effect of environmental pressure on the microstructure of YSZ thermal
							barrier coating via suspension plasma spraying, Journal of the European
							Ceramic Society (2020). ## [106] Y. Heng, N. Feng, Y. Liang, D. Hu,
							Lignin‐retaining porous bamboo‐based reversible thermochromic phase
							change energy storage composite material, International Journal of
							Energy Research 44(7) (2020) 5441-5454. ## [107] B. Mazères, C.
							Desgranges, C. Toffolon-Masclet, D. Monceau, Experimental study and
							numerical simulation of high temperature (1100–1250°C) oxidation of
							prior-oxidized zirconium alloy, Corrosion Science 103 (2016) 10-19. ##
							[108] D. Seo, M. Sayar, K. Ogawa, SiO2 and MoSi2 formation on Inconel
							625 surface via SiC coating deposited by cold spray, Surface and
							Coatings Technology 206(11-12) (2012) 2851-2858. ## [109] Y. Xu, X. Liu,
							L. Gu, J. Wang, P. Schützendübe, Y. Huang, Y. Liu, Z. Wang, Natural
							oxidation of amorphous CuxZr1-x alloys, Applied Surface Science 457
							(2018) 396-402. ## [110] K.R. Lim, W.T. Kim, E.-S. Lee, S.S. Jee, S.Y.
							Kim, D.H. Kim, A. Gebert, J. Eckert, Oxidation resistance of the
							supercooled liquid in Cu50Zr50 and Cu46Zr46Al8 metallic glasses, Journal
							of Materials Research 27(8) (2012) 1178. ## [111] B. Wang, D. Huang, N.
							Prud'Homme, Z. Chen, F. Jomard, T. Zhang, V. Ji, Diffusion mechanism of
							Zr-based metallic glass during oxidation under dry air, Intermetallics
							28 (2012) 102-107. ## [112] H. Over, A. Seitsonen, Oxidation of metal
							surfaces, Science 297(5589) (2002) 2003-2005. ## [113] S. Aygün, S.
							Klinge, Continuum mechanical modeling of strain-induced crystallization
							in polymers, International Journal of Solids and Structures 196-197
							(2020) 129-139. ## [114] Y. Wang, D. Su, H. Ji, X. Li, Z. Zhao, H. Tang,
							Gradient structure high emissivity MoSi2-SiO2-SiOC coating for thermal
							protective application, Journal of Alloys and Compounds 703 (2017)
							437-447. ## [115] X. Jing, H.-Y. Mi, X.-F. Peng, L.-S. Turng,
							Biocompatible, self-healing, highly stretchable polyacrylic acid/reduced
							graphene oxide nanocomposite hydrogel sensors via mussel-inspired
							chemistry, Carbon 136 (2018) 63-72. ## [116] T. Ouyang, S. Xiong, Y.
							Zhang, D. Liu, X. Fang, Y. Wang, S. Feng, T. Zhou, J. Suo, Cyclic
							oxidation behavior of SiC-containing self-healing TBC systems fabricated
							by APS, Journal of Alloys and Compounds 691 (2017) 811-821. ## [117]
							T.N. Son Thanh Nguyen, Masatoshi Takeda, Nguyen Ngoc Hieu, Tsuyoshi
							Takahashi, Development of Yttrium Titanate/Nickel Nanocomposites with
							Self Crack-Healing Ability and Potential Application as Thermal Barrier
							Coating Material, (2020). ## [118] I.I. Kurniadi Isnu, On the in situ
							encapsulation of MoSi2B healing particles in YSZ TBCs: Self-healing of
							thermal barrier coatings (TBCs), (2016). ## [119] V. Carnicer Cervera,
							E. Cañas-Recacha, M.J. Orts Tarí, R. Moreno, M.D. Salvador Moya, P.
							Carpio Cobo, L. Navarro, E. Sánchez-Vilches, Characterization of thermal
							barriers coatings of Y-TZP/Al2O3/SiC composite obtained by suspension
							plasma spraying, (2017). ## [120] B. Xiao, X. Huang, T. Robertson, Z.
							Tang, R. Kearsey, Sintering resistance of suspension plasma sprayed 7YSZ
							TBC under isothermal and cyclic oxidation, Journal of the European
							Ceramic Society 40(5) (2020) 2030-2041. ## [121] F. Nozahic, A.L.
							Carabat, W. Mao, D. Monceau, C. Estournès, C. Kwakernaak, S. Van Der
							Zwaag, W.G. Sloof, Kinetics of zircon formation in yttria partially
							stabilized zirconia as a result of oxidation of embedded molybdenum
							disilicide, Acta Materialia 174 (2019) 206-216.</REF>
					</REFRENCE>
				</REFRENCES>
			</ARTICLE>
			<ARTICLE>
				<LANGUAGE_ID>1</LANGUAGE_ID>
				<TitleF>-</TitleF>
				<TitleE>Filled FRP–PVC tubular columns for strengthening of concrete in the
					construction sector: A review</TitleE>
				<URL>https://www.jourcc.com/index.php/jourcc/article/view/jcc237</URL>
				<DOI>10.29252/jcc.2.3.7</DOI>
				<DOR/>
				<ABSTRACTS>
					<ABSTRACT>
						<LANGUAGE_ID>1</LANGUAGE_ID>
						<CONTENT>In recent years, fber-reinforced polymer-polyvinyl chloride
							(FRP-PVC) tubular columns have been used increasingly in civil
							engineering applications. Concrete-flled RP-PVC tubes possess high
							durability, high strengthening performance, satisfactory bond strength,
							and compressive behavior. It has been observed that these cost-eﬀective
							tubular columns are promising materials for enhancing strain capacities,
							strength, and stiﬀness of structures containing reinforced concrete
							(RC). These composite tubular columns are composed of FRP and PVC and
							are used for strengthening concrete. FRP enhances strength capacity
							while PVC improves the corrosion resistance of concrete piles in harsh
							environments. This review focuses on the properties of FRP-PVC tubular
							columns, their application in civil engineering, and the recent
							advancements in this feld.</CONTENT>
					</ABSTRACT>
					<ABSTRACT>
						<LANGUAGE_ID>0</LANGUAGE_ID>
						<CONTENT>-</CONTENT>
					</ABSTRACT>
				</ABSTRACTS>
				<PAGES>
					<PAGE>
						<FPAGE>155</FPAGE>
						<TPAGE>162</TPAGE>
					</PAGE>
				</PAGES>

				<AUTHORS>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Milad</NameE>
						<MidNameE/>
						<FamilyE>Bazli</FamilyE>
						<Organizations>
							<Organization>Department of Civil Engineering, Monash
								University</Organization>
						</Organizations>
						<Countries>
							<Country>Australia</Country>
						</Countries>
						<EMAILS>
							<Email>milad.bazli@monash.edu</Email>
						</EMAILS>
					</AUTHOR>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Leila</NameE>
						<MidNameE/>
						<FamilyE>Bazli</FamilyE>
						<Organizations>
							<Organization>School of Metallurgy and Materials Engineering, Iran
								University of Science and Technology</Organization>
						</Organizations>
						<Countries>
							<Country>Iran</Country>
						</Countries>
						<EMAILS>
							<Email>info@jourcc.com</Email>
						</EMAILS>
					</AUTHOR>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Roozbeh</NameE>
						<MidNameE/>
						<FamilyE>Rahmani</FamilyE>
						<Organizations>
							<Organization>Department of Civil Engineering, University of
								Tabriz</Organization>
						</Organizations>
						<Countries>
							<Country>Iran</Country>
						</Countries>
						<EMAILS>
							<Email>info@jourcc.com</Email>
						</EMAILS>
					</AUTHOR>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Sohail</NameE>
						<MidNameE/>
						<FamilyE>Mansoor</FamilyE>
						<Organizations>
							<Organization>Faculty of Engineering, Christian-Albrechts-University
								Kiel</Organization>
						</Organizations>
						<Countries>
							<Country>Germany</Country>
						</Countries>
						<EMAILS>
							<Email>info@jourcc.com</Email>
						</EMAILS>
					</AUTHOR>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Mohammad</NameE>
						<MidNameE/>
						<FamilyE>Ahmadi</FamilyE>
						<Organizations>
							<Organization>Faculty of Engineering, Christian-Albrechts-University
								Kiel</Organization>
						</Organizations>
						<Countries>
							<Country>Germany</Country>
						</Countries>
						<EMAILS>
							<Email>info@jourcc.com</Email>
						</EMAILS>
					</AUTHOR>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Rasul</NameE>
						<MidNameE/>
						<FamilyE>Pouriamanesh</FamilyE>
						<Organizations>
							<Organization>Mahshahr Pipe Mill Co. (MPM)</Organization>
						</Organizations>
						<Countries>
							<Country>Iran</Country>
						</Countries>
						<EMAILS>
							<Email>info@jourcc.com</Email>
						</EMAILS>
					</AUTHOR>
				</AUTHORS>
				<KEYWORDS>
					<KEYWORD>
						<KeyText>Reinforced concrete</KeyText>
					</KEYWORD>
					<KEYWORD>
						<KeyText>FRP–PVC</KeyText>
					</KEYWORD>
					<KEYWORD>
						<KeyText>Tubular columns</KeyText>
					</KEYWORD>
					<KEYWORD>
						<KeyText>Strengthening</KeyText>
					</KEYWORD>
					<KEYWORD>
						<KeyText>Durability</KeyText>
					</KEYWORD>
				</KEYWORDS>
				<REFRENCES>
					<REFRENCE>
						<REF>[1] S. Hemavathi, A. Sumil Kumaran, R. Sindhu, An experimental
							investigation on properties of concrete by using silica fume and glass
							fibre as admixture, Materials Today: Proceedings 21 (2020) 456-459. ##
							[2] M. Gunavel, S. Aishwarya, K. Indhumathi, N. Jalapriya, M.K. Priya,
							Proportioning of Lightweight Concrete by the Inclusion of Expanded
							Polystyrene (EPS), International Journal of Engineering Research and
							Technology 9(2) (2020). ## [3] L. Wang, Z. Yang, Y. Cui, B. Wei, S. Xu,
							J. Sheng, M. Wang, Y. Zhu, W. Fei, Graphene-copper composite with
							micro-layered grains and ultrahigh strength, Scientific Reports 7(1)
							(2017) 41896. ## [4] M. Bazli, X.-L. Zhao, R.S. Raman, Y. Bai, S.
							Al-Saadi, Bond performance between FRP tubes and seawater sea sand
							concrete after exposure to seawater condition, Construction and Building
							Materials 265 (2020) 120342. ## [5] S.-F. Jiang, S.-L. Ma, Z.-Q. Wu,
							Experimental study and theoretical analysis on slender concrete-filled
							CFRP–PVC tubular columns, Construction and Building Materials 53 (2014)
							475-487. ## [6] J. Teng, T. Yu, J. Dai, G. Chen, FRP composites in new
							construction: current status and opportunities, Proceedings of 7th
							National Conference on FRP Composites in Infrastructure (Supplementary
							Issue of Industrial Construction), keynote presentation, Hangzhou,
							China, 2011. ## [7] M. Bazli, X.-L. Zhao, A. Jafari, H. Ashrafi, Y. Bai,
							R.S. Raman, H. Khezrzadeh, Mechanical properties of pultruded GFRP
							profiles under seawater sea sand concrete environment coupled with UV
							radiation and moisture, Construction and Building Materials (2020)
							120369. ## [8] M. Fakharifar, G. Chen, Compressive behavior of
							FRP-confined concrete-filled PVC tubular columns, Composite Structures
							141 (2016) 91-109. ## [9] S. Saadi, B. Nazari, Recent developments and
							applications of nanocomposites in solar cells: a review, Journal of
							Composites and Compounds 1(1) (2019) 48-58. ## [10] Z. Yan, C.P.
							Pantelides, L.D. Reaveley, Posttensioned FRP composite shells for
							concrete confinement, Journal of Composites for Construction 11(1)
							(2007) 81-90. ## [11] K.N. Nesheli, K. Meguro, Seismic retrofitting of
							earthquake-damaged concrete columns by lateral pre-tensioning of FRP
							belts, Proc., 8th US National Conf. on Earthquake Engineering,
							Earthquake Engineering Research Institute (EERI) El Cerrito, CA, 2006.
							## [12] B. Wang, E.V. Bachtiar, L. Yan, B. Kasal, V. Fiore, Flax,
							Basalt, E-Glass FRP and Their Hybrid FRP Strengthened Wood Beams: An
							Experimental Study, Polymers 11(8) (2019) 1255. ## [13] T.C. Rousakis,
							I.S. Tourtouras, RC columns of square section–passive and active
							confinement with composite ropes, Composites Part B: Engineering 58
							(2014) 573-581. ## [14] M. Shin, B. Andrawes, Experimental investigation
							of actively confined concrete using shape memory alloys, Engineering
							Structures 32(3) (2010) 656-664. ## [15] E. Choi, B.-S. Cho, S. Lee,
							Seismic retrofit of circular RC columns through using tensioned GFRP
							wires winding, Composites Part B: Engineering 83 (2015) 216-225. ## [16]
							A.U. Al-saadi, T. Aravinthan, W. Lokuge, Structural applications of
							fibre reinforced polymer (FRP) composite tubes: A review of columns
							members, Composite Structures 204 (2018) 513-524. ## [17] M. Arefian, M.
							Hojjati, I. Tajzad, A. Mokhtarzade, M. Mazhar, A. Jamavari, A review of
							Polyvinyl alcohol/Carboxiy methyl cellulose (PVA/CMC) composites for
							various applications, Journal of Composites and Compounds 2(3) (2020)
							69-76. ## [18] A. Abuchenari, K. Hardani, S. Abazari, F. Naghdi, M.A.
							Keleshteri, A. Jamavari, A.M. Chahardehi, Clay-reinforced nanocomposites
							for the slow release of chemical fertilizers and water retention,
							Journal of Composites and Compounds 2(3) (2020) 85-91. ## [19] S.O.
							Omid, Z. Goudarzi, L.M. Kangarshahi, A. Mokhtarzade, F. Bahrami,
							Self-expanding stents based on shape memory alloys and shape memory
							polymers, Journal of Composites and Compounds 2(3) (2020) 92-98. ## [20]
							H.W. Jang, A. Zareidoost, M. Moradi, A. Abuchenari, A. Bakhtiari, R.
							Pouriamanesh, B. Malekpouri, A.J. Rad, D. Rahban, Photosensitive
							nanocomposites: environmental and biological applications, Journal of
							Composites and Compounds 2(1) (2020) 50-60. ## [21] A. Kazemzadeh, H.
							Kazemzadeh, Determination of Hg2+ by Diphenylcarbazone Compound in
							Polymer Film, Journal of Composites and Compounds 1(1) (2019) 30-35. ##
							[22] L. Bazli, M.H. Bagherian, M. Karrabi, F. Abbassi‐Sourki, H. Azizi,
							Effect of starch ratio and compatibilization on the viscoelastic
							behavior of POE/starch blends, Journal of Applied Polymer Science
							137(29) (2020) 48877. ## [23] P. Abasian, M. Radmansouri, M.H. Jouybari,
							M.V. Ghasemi, A. Mohammadi, M. Irani, F.S. Jazi, Incorporation of
							magnetic NaX zeolite/DOX into the PLA/chitosan nanofibers for sustained
							release of doxorubicin against carcinoma cells death in vitro,
							International journal of biological macromolecules 121 (2019) 398-406.
							## [24] M. Radmansouri, E. Bahmani, E. Sarikhani, K. Rahmani, F.
							Sharifianjazi, M. Irani, Doxorubicin hydrochloride-Loaded electrospun
							chitosan/cobalt ferrite/titanium oxide nanofibers for hyperthermic tumor
							cell treatment and controlled drug release, International journal of
							biological macromolecules 116 (2018) 378-384. ## [25] B.F. Dizaji, M.H.
							Azerbaijan, N. Sheisi, P. Goleij, T. Mirmajidi, F. Chogan, M. Irani, F.
							Sharafian, Synthesis of PLGA/chitosan/zeolites and PLGA/chitosan/metal
							organic frameworks nanofibers for targeted delivery of Paclitaxel toward
							prostate cancer cells death, International Journal of Biological
							Macromolecules (2020). ## [26] L. Bazli, A. Khavandi, M.A. Boutorabi, M.
							Karrabi, Morphology and viscoelastic behavior of silicone
							rubber/EPDM/Cloisite 15A nanocomposites based on Maxwell model, Iranian
							Polymer Journal 25(11) (2016) 907-918. ## [27] L. Bazli, A. Khavandi,
							M.A. Boutorabi, M. Karrabi, Correlation between viscoelastic behavior
							and morphology of nanocomposites based on SR/EPDM blends compatibilized
							by maleic anhydride, Polymer 113 (2017) 156-166. ## [28] A. Kazemzadeh,
							M.A. Meshkat, H. Kazemzadeh, M. Moradi, R. Bahrami, R. Pouriamanesh,
							Preparation of graphene nanolayers through surfactant-assisted pure
							shear milling method, Journal of Composites and Compounds 1(1) (2019)
							25-30. ## [29] M. Bazli, X.-L. Zhao, A. Jafari, H. Ashrafi, R.S. Raman,
							Y. Bai, H. Khezrzadeh, Durability of glass-fibre-reinforced polymer
							composites under seawater and sea-sand concrete coupled with harsh
							outdoor environments, Advances in Structural Engineering (2020)
							1369433220947897. ## [30] Z. Huang, D. Li, B. Uy, H.-T. Thai, C. Hou,
							Local and post-local buckling of fabricated high-strength steel and
							composite columns, Journal of Constructional Steel Research 154 (2019)
							235-249. ## [31] D. Li, Z. Huang, B. Uy, H.-T. Thai, C. Hou, Slenderness
							limits for fabricated S960 ultra-high-strength steel and composite
							columns, Journal of Constructional Steel Research 159 (2019) 109-121. ##
							[32] H. Ashrafi, M. Bazli, A.V. Oskouei, Enhancement of bond
							characteristics of ribbed-surface GFRP bars with concrete by using
							carbon fiber mat anchorage, Construction and Building Materials 134
							(2017) 507-519. ## [33] M. Bazli, H. Ashrafi, A.V. Oskouei, Experiments
							and probabilistic models of bond strength between GFRP bar and different
							types of concrete under aggressive environments, Construction and
							Building Materials 148 (2017) 429-443. ## [34] M. Bazli, Y.L. Li, X.L.
							Zhao, R.S. Raman, Y. Bai, S. Al-Saadi, A. Haque, Durability of seawater
							and sea sand concrete filled filament wound FRP tubes under seawater
							environments, Composites Part B: Engineering (2020) 108409. ## [35] J.
							Wang, P. Feng, T. Hao, Q. Yue, Axial compressive behavior of seawater
							coral aggregate concrete-filled FRP tubes, Construction and Building
							Materials 147 (2017) 272-285. ## [36] M. Bazli, X.-L. Zhao, Y. Bai, R.S.
							Raman, S. Al-Saadi, A. Haque, Durability of pultruded GFRP tubes
							subjected to seawater sea sand concrete and seawater environments,
							Construction and Building Materials 245 (2020) 118399. ## [37] M. Bazli,
							X.-L. Zhao, Y. Bai, R.S. Raman, S. Al-Saadi, Bond-slip behaviour between
							FRP tubes and seawater sea sand concrete, Engineering Structures 197
							(2019) 109421. ## [38] Y.L. Li, X.L. Zhao, R.K. Raman Singh , S.
							Al-Saadi, Tests on seawater and sea sand concrete-filled CFRP, BFRP and
							stainless steel tubular stub columns, Thin-Walled Structures 108 (2016)
							163-184. ## [39] Y.L. Li, X.L. Zhao, R.K. Raman Singh , S. Al-Saadi,
							Experimental study on seawater and sea sand concrete filled GFRP and
							stainless steel tubular stub columns, Thin-Walled Structures 106 (2016)
							390-406. ## [40] G.M. Chen, Z.B. He, T. Jiang, J.F. Chen, J.G. Teng,
							Axial compression tests on FRP-confined seawater/sea-sand concrete, 6th
							Asia-Pacific Conference on FRP in Structures, 2017. ## [41] Y.L. Li,
							J.G. Teng, X.L. Zhao, R.K. Singh Raman, Theoretical model for seawater
							and sea sand concrete-filled circular FRP tubular stub columns under
							axial compression, Engineering Structures 160 (2018) 71-84. ## [42] C.
							Lu, A. Fam, The effect of tube damage on flexural strength of±55°
							angle-ply concrete-filled FRP tubes, Construction and Building Materials
							240 (2020) 117948. ## [43] H. Tian, Z. Zhou, Y. Wei, J. Lu, Behavior and
							Modeling of Ultra-High Performance Concrete-Filled FRP Tubes Under
							Cyclic Axial Compression, Journal of Composites for Construction 24(5)
							(2020) 04020045. ## [44] A.M. Ali, R. Masmoudi, Composite Action
							Assessment of Concrete-Filled FRP Tubes Subjected to Flexural Cyclic
							Load, Engineering Structures 203 (2020) 109889. ## [45] H. Lee, H. Jang,
							W. Chung, Effect of Recycled Concrete on the Flexural Behavior of
							Concrete-Filled FRP Tubes, International Journal of Concrete Structures
							and Materials 13(1) (2019) 12. ## [46] A.F. Pour, A. Gholampour, J.
							Zheng, T. Ozbakkaloglu, Behavior of FRP-confined high-strength concrete
							under eccentric compression: tests on concrete-filled FRP tube columns,
							Composite Structures 220 (2019) 261-272. ## [47] Z. Chen, J. Wang, J.
							Chen, H. GangaRao, R. Liang, W. Liu, Responses of concrete-filled FRP
							tubular and concrete-filled FRP-steel double skin tubular columns under
							horizontal impact, Thin-Walled Structures 155 (2020) 106941. ## [48] H.
							Tian, Z. Zhou, Y. Wei, Y. Wang, J. Lu, Experimental investigation on
							axial compressive behavior of ultra-high performance concrete (UHPC)
							filled glass FRP tubes, Construction and Building Materials 225 (2019)
							678-691. ## [49] Y. Zhang, Y. Wei, J. Bai, Y. Zhang, Stress-strain model
							of an FRP-confined concrete filled steel tube under axial compression,
							Thin-Walled Structures 142 (2019) 149-159. ## [50] Y.-L. Li, X.-L. Zhao,
							R.S. Raman, Behaviour of seawater and sea sand concrete filled FRP
							square hollow sections, Thin-Walled Structures 148 (2020) 106596. ##
							[51] A.M. Ali, R. Masmoudi, Experimental and analytical investigation of
							new concrete filled FRP tube beam-column connections, Engineering
							Structures 191 (2019) 311-322. ## [52] Y. Zhang, Y. Wei, J. Bai, G. Wu,
							Z. Dong, A novel seawater and sea sand concrete filled FRP-carbon steel
							composite tube column: Concept and behaviour, Composite Structures
							(2020) 112421. ## [53] P. Xie, G. Lin, J. Teng, T. Jiang, Modelling of
							concrete-filled filament-wound FRP confining tubes considering nonlinear
							biaxial tube behavior, Engineering Structures 218 (2020) 110762. ## [54]
							M.J. Abyaneh, H. El Naggar, P. Sadeghian, Numerical Modeling of the
							Lateral Behavior of Concrete-Filled FRP Tube Piles in Sand,
							International Journal of Geomechanics 20(8) (2020) 04020108. ## [55] K.
							Gonnade, R. Khapre, Experimental and Computational Study on Concrete
							Filled PVC Plastic Tubes Placed In Columns, Helix 10(01) (2020) 165-169.
							## [56] S.M. Askari, A. Khaloo, M.H. Borhani, M.S.T. Masoule,
							Performance of polypropylene fiber reinforced concrete-filled UPVC tube
							columns under axial compression, Construction and Building Materials 231
							(2020) 117049. ## [57] Ö.B. Ceran, B. Şimşek, T. Uygunoğlu, O.N. Şara,
							PVC concrete composites: comparative study with other polymer concrete
							in terms of mechanical, thermal and electrical properties, Journal of
							Material Cycles and Waste Management 21(4) (2019) 818-828. ## [58] C.
							Gao, L. Huang, L. Yan, R. Jin, B. Kasal, Strength and ductility
							improvement of recycled aggregate concrete by polyester FRP-PVC tube
							confinement, Composites Part B: Engineering 162 (2019) 178-197. ## [59]
							F. Yu, D. Li, D. Niu, D. Zhu, Z. Kong, N. Zhang, Y. Fang, A model for
							ultimate bearing capacity of PVC-CFRP confined concrete column with
							reinforced concrete beam joint under axial compression, Construction and
							Building Materials 214 (2019) 668-676. ## [60] F. Yu, Z. Song, I.
							Mansouri, J. Liu, Y. Fang, Experimental study and finite element
							analysis of PVC-CFRP confined concrete column–Ring beam joint subjected
							to eccentric compression, Construction and Building Materials 254 (2020)
							119081. ## [61] H. Zhang, M.N. Hadi, Geogrid-confined pervious
							geopolymer concrete piles with FRP-PVC-confined concrete core:
							Analytical models, Structures, Elsevier, 2020, pp. 731-738. ## [62] F.
							Yu, N. Zhang, Y. Fang, J. Liu, G. Xiang, Stress-strain model of weak
							PVC-FRP confined concrete column and strong RC ring beam joint under
							eccentric compression, Steel and Composite Structures 35(1) (2020)
							13-27. ## [63] Y.-C. Guo, S.-H. Xiao, S.-W. Shi, J.-J. Zeng, W.-Q. Wang,
							H.-C. Zhao, Axial Compressive Behavior of Concrete-Filled FRP-Steel Wire
							Reinforced Thermoplastics Pipe Hybrid Columns, Composite Structures
							(2020) 112237. ## [64] Z. Wu, Y. Wu, M.F.M. Fahmy, 6 - FRP strengthening
							of concrete columns, in: Z. Wu, Y. Wu, M.F.M. Fahmy (Eds.), Structures
							Strengthened with Bonded Composites, Woodhead Publishing2020, pp.
							387-480. ## [65] F.E. Richart, A. Brandtzæg, R.L. Brown, A study of the
							failure of concrete under combined compressive stresses, University of
							Illinois at Urbana Champaign, College of Engineering …, 1928. ## [66]
							Y.M. Amran, R. Alyousef, R.S. Rashid, H. Alabduljabbar, C.-C. Hung,
							Properties and applications of FRP in strengthening RC structures: A
							review, Structures, Elsevier, 2018, pp. 208-238. ## [67] M.H.
							Khaneghahi, E.P. Najafabadi, M. Bazli, A.V. Oskouei, X.-L. Zhao, The
							effect of elevated temperatures on the compressive section capacity of
							pultruded GFRP profiles, Construction and Building Materials 249 (2020)
							118725. ## [68] H. Ashrafi, M. Bazli, A. Jafari, T. Ozbakkaloglu,
							Tensile properties of GFRP laminates after exposure to elevated
							temperatures: Effect of fiber configuration, sample thickness, and time
							of exposure, Composite Structures 238 (2020) 111971. ## [69] E.P.
							Najafabadi, M. Bazli, H. Ashrafi, A.V. Oskouei, Effect of applied stress
							and bar characteristics on the short-term creep behavior of FRP bars,
							Construction and Building Materials 171 (2018) 960-968. ## [70] A.V.
							Oskouei, A. Jafari, M. Bazli, R. Ghahri, Effect of different
							retrofitting techniques on in-plane behavior of masonry wallettes,
							Construction and Building Materials 169 (2018) 578-590. ## [71] A.V.
							Oskouei, M.P. Kivi, H. Araghi, M. Bazli, Experimental study of the
							punching behavior of GFRP reinforced lightweight concrete footing,
							Materials and Structures 50(6) (2017) 256. ## [72] A. Jafari, A.V.
							Oskouei, M. Bazli, R. Ghahri, Effect of the FRP sheet's arrays and NSM
							FRP bars on in-plane behavior of URM walls, Journal of Building
							Engineering 20 (2018) 679-695. ## [73] M.N.S. Hadi, Q.S. Khan, M.N.
							Sheikh, Axial and flexural behavior of unreinforced and FRP bar
							reinforced circular concrete filled FRP tube columns, Construction and
							Building Materials 122 (2016) 43-53. ## [74] A.D. Mai, M.N. Sheikh,
							M.N.S. Hadi, Investigation on the behaviour of partial wrapping in
							comparison with full wrapping of square RC columns under different
							loading conditions, Construction and Building Materials 168 (2018)
							153-168. ## [75] A. Kashi, A.A. Ramezanianpour, F. Moodi, Durability
							evaluation of retrofitted corroded reinforced concrete columns with FRP
							sheets in marine environmental conditions, Construction and Building
							Materials 151 (2017) 520-533. ## [76] A.N. Ababneh, R.Z. Al-Rousan, I.M.
							Ghaith, Experimental study on anchoring of FRP-strengthened concrete
							beams, Structures, Elsevier, 2020, pp. 26-33. ## [77] H. Zhang, M.N.S.
							Hadi, Geogrid-confined pervious geopolymer concrete piles with
							FRP-PVC-confined concrete core: Analytical models, Structures 23 (2020)
							731-738. ## [78] F. Micelli, R. Mazzotta, M. Leone, M.A. Aiello, Review
							Study on the Durability of FRP-Confined Concrete, Journal of Composites
							for Construction 19(3) (2015) 04014056. ## [79] H. Zhang, M.N. Hadi,
							Geogrid-confined pervious geopolymer concrete piles with
							FRP-PVC-confined concrete core: Concept and behaviour, Construction and
							Building Materials 211 (2019) 12-25. ## [80] X. Yang, W.-Y. Gao, J.-G.
							Dai, Z.-D. Lu, Shear strengthening of RC beams with FRP grid-reinforced
							ECC matrix, Composite Structures (2020) 112120. ## [81] Y. Wang, G.
							Chen, B. Wan, G. Cai, Y. Zhang, Behavior of circular ice-filled
							self-luminous FRP tubular stub columns under axial compression,
							Construction and Building Materials 232 (2020) 117287. ## [82] M.
							Lindner, K. Vanselow, S. Gelbrich, L. Kroll, Fibre-reinforced polymer
							stirrup for reinforcing concrete structures. ## [83] M. Tomii, Lateral
							Load Capacity of Reinforced Concrete Short Columns Confined by Stell
							Tube-Experimental Results of Preliminary Research, Proceedings of the
							International Specialty Confernce on Concrete-Filled Steel Tubular
							Structures (1985) 19-26. ## [84] M. Tomii, K. Sakino, Y. Xiao, K.
							Watanabe, Earthquake resisting hysteretic behavior of reinforced
							concrete short columns confined by steel tube, Proceedings of the
							International Speciality Conference on Concrete Filled Steel Tubular
							Structures, Harbin, China, 1985, pp. 119-25. ## [85] Y. Xiao,
							Applications of FRP composites in concrete columns, Advances in
							Structural Engineering 7(4) (2004) 335-343. ## [86] A. Raza, A. ur
							Rehman, B. Masood, I. Hussain, Finite element modelling and theoretical
							predictions of FRP-reinforced concrete columns confined with various
							FRP-tubes, Structures, Elsevier, 2020, pp. 626-638. ## [87] T.
							Ozbakkaloglu, T. Vincent, Axial compressive behavior of circular
							high-strength concrete-filled FRP tubes, Journal of composites for
							construction 18(2) (2014) 04013037. ## [88] Y.L. Li, X.L. Zhao, R.K.
							Singh Raman, Mechanical properties of seawater and sea sand
							concrete-filled FRP tubes in artificial seawater, Construction and
							Building Materials 191 (2018) 977-993. ## [89] A. Parghi, M.S. Alam, A
							review on the application of sprayed-FRP composites for strengthening of
							concrete and masonry structures in the construction sector, Composite
							Structures 187 (2018) 518-534. ## [90] C.E. Kurt, Concrete filled
							structural plastic columns, Journal of the Structural Division 104(ASCE
							13478 Proceeding) (1978). ## [91] R.K. Watkins, Buried pipe encased in
							concrete, Pipeline Engineering and Construction: What's on the
							Horizon?2004, pp. 1-10. ## [92] J. Xue, H. Li, L. Zhai, X. Ke, W. Zheng,
							B. Men, Analysis on influence parameters and mechanical behaviors of
							embedded PVC pipe confined with reinforced high-strength concrete
							columns under cyclic reversed loading, Xi’an University of Arch. and
							Tech.(natural science edition) 48(1) (2016). ## [93] W.O. Oyawa, N.K.
							Gathimba, N. Geoffrey, Innovative composite concrete filled plastic
							tubes in compression, 2015 World Congress on Advances in Structural
							Engineering and Mechanics (ASEM15), 2015, pp. 1-15. ## [94] J.-Y. Wang,
							Q.-B. Yang, Investigation on compressive behaviors of thermoplastic pipe
							confined concrete, Construction and Building Materials 35 (2012)
							578-585. ## [95] N.A. Abdulla, Concrete filled PVC tube: A review,
							Construction and Building Materials 156 (2017) 321-329. ## [96] H.
							Toutanji, M. Saafi, Durability studies on concrete columns encased in
							PVC–FRP composite tubes, Composite structures 54(1) (2001) 27-35. ##
							[97] J. Wang, Q. Yang, Experimental study on mechanical properties of
							concrete confined with plastic pipe, ACI Materials Journal 107(2) (2010)
							132. ## [98] R. Nowack, O.I. Otto, E.W. Braun, 60 Jahre Erfahrungen mit
							Rohrleitungen aus weichmacherfreiem Polyvinylchlorid (PVC-U), KRV
							Nachrichten (1995) 1-95. ## [99] P.K. Gupta, V.K. Verma, Study of
							concrete-filled unplasticized poly-vinyl chloride tubes in marine
							environment, Proceedings of the Institution of Mechanical Engineers,
							Part M: Journal of Engineering for the Maritime Environment 230(2)
							(2016) 229-240. ## [100] I. Jakubowicz, N. Yarahmadi, T. Gevert, Effects
							of accelerated and natural ageing on plasticized polyvinyl chloride
							(PVC), Polymer degradation and stability 66(3) (1999) 415-421. ## [101]
							A.S. Saadoon, Experimental and Theoretical Investigation of PVC Concrete
							composite Columns, University of Basrah (2010). ## [102] H. Zhang,
							M.N.S. Hadi, Geogrid-confined pervious geopolymer concrete piles with
							FRP-PVC-confined concrete core: Concept and behaviour, Construction and
							Building Materials 211 (2019) 12-25. ## [103] G. Zong, J. Hao, X. Hao,
							Y. Fang, Y. Song, H. Wang, R. Ou, Q. Wang, Enhancing the flame
							retardancy and mechanical properties of veneered wood flour/polyvinyl
							chloride composites, Polymer Composites 41(3) (2020) 848-857. ## [104]
							H. Toutanji, M. Saafi, Stress-strain behavior of concrete columns
							confined with hybrid composite materials, Materials and structures 35(6)
							(2002) 338. ## [105] M. Marzouck, K. Sennah, Concrete-filled PVC tubes
							as compression members, Composite Materials in Concrete Construction:
							Proceedings of the International Seminar held at the University of
							Dundee, Scotland, UK on 5–6 September 2002, Thomas Telford Publishing,
							2002, pp. 31-37. ## [106] F. Yu, D. Niu, Stress-strain model of PVC-FRP
							confined concrete column subjected to axial compression, Academic
							Journals, 2010. ## [107] Y. Fang, F. Yu, Y. Guan, Z. Wang, C. Feng, D.
							Li, A model for predicting the stress–strain relation of PVC-CFRP
							confined concrete stub columns under axial compression, Structures,
							Elsevier, 2020, pp. 259-270. ## [108] S.-F. Jiang, S.-L. Ma, C.-L.
							Liang, Z.-Q. Wu, Axial Behavior of CFRP-PVC-Confined Concrete Stubs,
							Advanced Science Letters 9(1) (2012) 197-203. ## [109] A.M. Mammen, M.
							Antony, Experimental Study On Frp-Pvc Confined Circular Columns,
							International Research Journal of Engineering and Technology (IRJET)
							4(5) (2017). ## [110] Y. Yu, Z. Wu, H. Guan, Experimental Study On The
							Axial Compression Of GRP-Concrete-PVC Tube Composite Column, IOP
							Conference Series: Earth and Environmental Science, IOP Publishing,
							2019, p. 042013. ## [111] H. Toutanji, Design equations for concrete
							columns confined with hybrid composite materials, Advanced Composite
							Materials 10(2-3) (2001) 127-138. ## [112] A.M. Woldemariam, W.O. Oyawa,
							T. Nyomboi, The Behavior of Concrete-Filled Single and Double-Skin uPVC
							Tubular Columns Under Axial Compression Loads, The Open Construction and
							Building Technology Journal 13(1) (2019). ## [113] F. Hong-bo, Mechanics
							behavior of FRP-PVC concrete column [j], Low Temperature Architecture
							Technology 5 (2009). ## [114] Y. Qi-bin, New progress on the study of a
							new type of hybrid columns based on FRP and PVC [J], Journal of
							Changchun Institute of Technology (Natural Sciences Edition) 1 (2011).
							## [115] M. Fakharifar, G. Chen, FRP-confined concrete filled PVC tubes:
							A new design concept for ductile column construction in seismic regions,
							Construction and Building Materials 130 (2017) 1-10. ## [116] F. Yu, G.
							Xu, D. Niu, A. Cheng, P. Wu, Z. Kong, Experimental study on PVC-CFRP
							confined concrete columns under low cyclic loading, Construction and
							Building Materials 177 (2018) 287-302. ## [117] M. Bazli, A. Jafari, H.
							Ashrafi, X.-L. Zhao, Y. Bai, R.S. Raman, Effects of UV radiation,
							moisture and elevated temperature on mechanical properties of GFRP
							pultruded profiles, Construction and Building Materials 231 (2020)
							117137. ## [118] M. Bazli, H. Ashrafi, A.V. Oskouei, Effect of harsh
							environments on mechanical properties of GFRP pultruded profiles,
							Composites Part B: Engineering 99 (2016) 203-215. ## [119] F. Micelli,
							A. Nanni, Durability of FRP rods for concrete structures, Construction
							and Building materials 18(7) (2004) 491-503. ## [120] D. Lau, Q. Qiu, A.
							Zhou, C.L. Chow, Long term performance and fire safety aspect of FRP
							composites used in building structures, Construction and building
							materials 126 (2016) 573-585. ## [121] G. Wu, X. Wang, Z. Wu, Z. Dong,
							G. Zhang, Durability of basalt fibers and composites in corrosive
							environments, Journal of Composite Materials 49(7) (2015) 873-887. ##
							[122] M. Bazli, H. Ashrafi, A. Jafari, X.-L. Zhao, R. Raman, Y. Bai,
							Effect of fibers configuration and thickness on tensile behavior of GFRP
							laminates exposed to harsh environment, Polymers 11(9) (2019) 1401. ##
							[123] H. Ashrafi, M. Bazli, E.P. Najafabadi, A.V. Oskouei, The effect of
							mechanical and thermal properties of FRP bars on their tensile
							performance under elevated temperatures, Construction and Building
							Materials 157 (2017) 1001-1010. ## [124] H. Ashrafi, M. Bazli, A. Vatani
							Oskouei, L. Bazli, Effect of sequential exposure to UV radiation and
							water vapor condensation and extreme temperatures on the mechanical
							properties of GFRP bars, Journal of Composites for Construction 22(1)
							(2018) 04017047. ## [125] M. Bazli, H. Ashrafi, A. Jafari, X.-L. Zhao,
							H. Gholipour, A.V. Oskouei, Effect of thickness and reinforcement
							configuration on flexural and impact behaviour of GFRP laminates after
							exposure to elevated temperatures, Composites Part B: Engineering 157
							(2019) 76-99. ## [126] A.V. Oskouei, M. Bazli, H. Ashrafi, M. Imani,
							Flexural and web crippling properties of GFRP pultruded profiles
							subjected to wetting and drying cycles in different sea water
							conditions, Polymer Testing 69 (2018) 417-430. ## [127] A. Jafari, M.
							Bazli, H. Ashrafi, A.V. Oskouei, S. Azhari, X.-L. Zhao, H. Gholipour,
							Effect of fibers configuration and thickness on tensile behavior of GFRP
							laminates subjected to elevated temperatures, Construction and Building
							Materials 202 (2019) 189-207. ## [128] M. Bazli, X.L. Zhao, R.S. Raman,
							Y. Bai, S. Al-Saadi, Bond strength durability between FRP tubes and
							seawater sea sand concrete under sea water condition, Asia-Pacific
							Conference on FRP in Structures 2019, APFIS Conference Series, 2019. ##
							[129] H.A. Toutanji, L. Zhao, G.J. Isaacs, Durability studies on
							concrete columns confined with advanced fibre composites, International
							Journal of materials and product technology 28(1-2) (2007) 8-28.##</REF>
					</REFRENCE>
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