<?xml version="1.0" encoding="utf-8"?>
<XML>
	<JOURNAL>
		<YEAR>2020</YEAR>
		<VOL>2</VOL>
		<NO>5</NO>
		<MOSALSAL>5</MOSALSAL>
		<PAGE_NO>78</PAGE_NO>
		<ARTICLES>


			<ARTICLE>
				<LANGUAGE_ID>1</LANGUAGE_ID>
				<TitleF>-</TitleF>
				<TitleE>Characterization of TiB 2 reinforced aluminum matrix composite synthesized by in situ stir casting method</TitleE>
				<URL>https://jourcc.com/index.php/jourcc/article/view/jcc241</URL>
				<DOI>10.29252/jcc.2.4.1</DOI>
				<DOR/>
				<ABSTRACTS>
					<ABSTRACT>
						<LANGUAGE_ID>1</LANGUAGE_ID>
						<CONTENT>In this study, TiB2 reinforced Al-matrix composite was fabricated by in situ stir casting route, and the effect of processing parameters was investigated. X-ray diffraction (XRD) and field emission scanning electron microscopy (FE-SEM) equipped with energy-dispersive X-ray spectroscopy (EDX) were used to study the composition and microstructure of the samples. Finally, to investigate the tribological and electrochemical behavior of the samples, wear tests (pin-on-disk) and potentiodynamic polarization tests (PDP) were used, respectively. Results showed that by increasing stirring time, both tribological and mechanical behavior of the samples improved. Also, it was found that by increasing the stirring speed of the melt to 180 rpm, the mechanical and tribological behavior of the samples improved, and by further increasing the stirring speed to 300 rpm, they were decreased. Consequently, samples containing lower than 7 wt. % TiB2 showed better metallurgical properties, due to lack of agglomeration.</CONTENT>
					</ABSTRACT>
					<ABSTRACT>
						<LANGUAGE_ID>0</LANGUAGE_ID>
						<CONTENT>-</CONTENT>
					</ABSTRACT>
				</ABSTRACTS>
				<PAGES>
					<PAGE>
						<FPAGE>163</FPAGE>
						<TPAGE>170</TPAGE>
					</PAGE>
				</PAGES>

				<AUTHORS>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Fereshteh</NameE>
						<MidNameE/>
						<FamilyE>Barragh Jam</FamilyE>
						<Organizations>
							<Organization>Department of Chemical Engineering, University of Maragheh</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>Bangi Houri</FamilyE>
						<Organizations>
							<Organization>Department of Materials and Metallurgical Engineering, Ferdowsi University of Mashhad</Organization>
						</Organizations>
						<Countries>
							<Country>Iran</Country>
						</Countries>
						<EMAILS>
							<Email>Pers73hadi@gmail.com</Email>
						</EMAILS>
					</AUTHOR>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Morteza</NameE>
						<MidNameE/>
						<FamilyE>Ferdosi</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>
				</AUTHORS>
				<KEYWORDS>
					<KEYWORD>
						<KeyText>In situ</KeyText>
					</KEYWORD>
					<KEYWORD>
						<KeyText>Composite</KeyText>
					</KEYWORD>
					<KEYWORD>
						<KeyText>TiB2</KeyText>
					</KEYWORD>
					<KEYWORD>
						<KeyText>Wear resistance</KeyText>
					</KEYWORD>
					<KEYWORD>
						<KeyText>Stir casting</KeyText>
					</KEYWORD>
				</KEYWORDS>
				<REFRENCES>
					<REFRENCE>
						<REF>[1] A.M. Davitoiu, E. Truta, A.M. Mitu, A.A. Bojescu, F. Grama, M. Ionica, The Role of Aluminum in the Symptomatology of Attention Deficit Hyperactivity Disorder Children, Res. and Sci. Today 1 (2018) 115. ##[2] C.C.T. Leussa, L. Libessart, C. Djelal, C.N. Djangang, A. Elimbi, Pozzolanic activity of kaolins containing aluminum hydroxide, Scientific Reports 10(1) (2020) 1-12. ##[3] A. Bigham, A.H. Aghajanian, M. Movahedi, M. Sattary, M. Rafienia, L. Tayebi, A 3D nanostructured calcium-aluminum-silicate scaffold with hierarchical meso-macroporosity for bone tissue regeneration: Fabrication, sintering behavior, surface modification and in vitro studies, Journal of the European Ceramic Society (2020). ##[4] L.S. Fard, N.S. Peighambardoust, H.W. Jang, A. Dehghan, N.N.K. Saligheh, M. Iranpour, M.I. Rajabi, The rechargeable aluminum-ion battery with different composite cathodes: A review, Journal of Composites and Compounds 2(4) (2020) 138-146. ##[5] D.-L. Vu, N. Kim, Y. Myung, M. Yang, J.-w. Lee, Aluminum phosphate as a bifunctional additive for improved cycling stability of Li-S batteries, Journal of Power Sources 459 (2020) 228068. ##[6] J.L. Domingo, J. Llobet, M. Gomez, J. Tomas, J. Corbella, Nutritional and toxicological effects of short-term ingestion of aluminum by the rat, Research communications in chemical pathology and pharmacology 56(3) (1987) 409. ##[7] V.T. Targhi, H. Omidvar, F. Sharifianjazi, A. Pakseresht, Hot corrosion behavior of aluminized and Si-modified aluminized coated IN-738LC produced by a novel hot-dip process, Surfaces and Interfaces 21 (2020) 100599. ##[8] M.G. Soni, S.M. White, W.G. Flamm, G.A. Burdock, Safety evaluation of dietary aluminum, Regulatory toxicology and pharmacology 33(1) (2001) 66-79. ##[9] 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. ##[10] Y. Zhang, N. Ma, H. Wang, Y. Le, X. Li, Damping capacity of in situ TiB2 particulates reinforced aluminium composites with Ti addition, Materials and design 28(2) (2007) 628-632. ##[11] S. Jayalakshmi, S. Gupta, S. Sankaranarayanan, S. Sahu, M. Gupta, Structural and mechanical properties of Ni60Nb40 amorphous alloy particle reinforced Al-based composites produced by microwave-assisted rapid sintering, Materials Science and Engineering: A 581 (2013) 119-127. ##[12] 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). ##[13] S.A. Sajjadi, H.R. Ezatpour, M. Torabi Parizi, Comparison of microstructure and mechanical properties of A356 aluminum alloy/Al2O3 composites fabricated by stir and compo-casting processes, Materials and Design 34 (2012) 106-111. ##[14] P. Poddar, V.C. Srivastava, P.K. De, K.L. Sahoo, Processing and mechanical properties of SiC reinforced cast magnesium matrix composites by stir casting process, Materials Science and Engineering: A 460-461 (2007) 357-364. ##[15] S. Gopalakrishnan, N. Murugan, Production and wear characterisation of AA 6061 matrix titanium carbide particulate reinforced composite by enhanced stir casting method, Composites Part B: Engineering 43(2) (2012) 302-308. ##[16] B. Leila, S. Mostafa, S. Arman, A review of carbon nanotube/TiO2 composite prepared via sol-gel method, Journal of Composites and Compounds 1(1) (2019). ##[17] S. Kumar, M. Chakraborty, V. Subramanya Sarma, B.S. Murty, Tensile and wear behaviour of in situ Al–7Si/TiB2 particulate composites, Wear 265(1) (2008) 134-142. ##[18] C.S. Ramesh, A. Ahamed, Friction and wear behaviour of cast Al 6063 based in situ metal matrix composites, Wear 271(9) (2011) 1928-1939. ##[19] M. Emamy, M. Mahta, J. Rasizadeh, Formation of TiB2 particles during dissolution of TiAl3 in Al–TiB2 metal matrix composite using an in situ technique, Composites Science and Technology 66(7) (2006) 1063-1066. ##[20] S. Lakshmi, L. Lu, M. Gupta, In situ preparation of TiB2 reinforced Al based composites, Journal of Materials Processing Technology 73(1) (1998) 160-166. ##[21] Q. Zhang, B.L. Xiao, W.G. Wang, Z.Y. Ma, Reactive mechanism and mechanical properties of in situ composites fabricated from an Al–TiB2 system by friction stir processing, Acta Materialia 60(20) (2012) 7090-7103. ##[22] D.G. Zhao, X.F. Liu, Y.C. Pan, X.F. Bian, X.J. Liu, Microstructure and mechanical properties of in situ synthesized (TiB2+Al2O3)/Al–Cu composites, Journal of Materials Processing Technology 189(1) (2007) 237-241. ##[23] A. Masoudian, A. Tahaei, A. Shakiba, F. Sharifianjazi, J.A. Mohandesi, Microstructure and mechanical properties of friction stir weld of dissimilar AZ31-O magnesium alloy to 6061-T6 aluminum alloy, Transactions of nonferrous metals society of China 24(5) (2014) 1317-1322. ##[24] H. Morteza Ferdosi, E. Sara, D. Alireza, Ni-Cu matrix composite reinforced with CNTs: preparation, characterization, wear and corrosion behavior, inhibitory effects, Journal of Composites and Compounds 2(4) (2020). ##[25] S. Suresh, N. Shenbag, V. Moorthi, Aluminium-Titanium Diboride (Al-TiB2) Metal Matrix Composites: Challenges and Opportunities, Procedia Engineering 38 (2012) 89-97. ##[26] A.C. Reddy, Investigation of the Clustering Behavior of Titanium Diboride Particles in TiB2/AA2024 Alloy Metal Matrix Composites, 4th International Conference on Composite Materials and Characterization, Hyderabad, India, 2003, pp. 216-220. ##[27] B. Basu, G. Raju, A. Suri, Processing and properties of monolithic TiB2 based materials, International materials reviews 51(6) (2006) 352-374. ##[28] A. Aliasghar, M. Mostafa, The Effect of Cu-substitution on the microstructure and magnetic properties of Fe-15%Ni alloy prepared by mechanical alloying, Journal of Composites and Compounds 1(1) (2019). ##[29] 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. ##[30] F. Chen, Z. Chen, F. Mao, T. Wang, Z. Cao, TiB2 reinforced aluminum based in situ composites fabricated by stir casting, Materials Science and Engineering: A 625 (2015) 357-368. ##[31] Y. Pazhouhanfar, B. Eghbali, Microstructural characterization and mechanical properties of TiB2 reinforced Al6061 matrix composites produced using stir casting process, Materials Science and Engineering: A 710 (2018) 172-180. ##[32] A.C. Reddy, Fracture behaviour of brittle matrix and alumina trihydrate particulate composites, (2002). ##[33] Z. Sadeghian, M.H. Enayati, P. Beiss, In situ production of Al–TiB2 nanocomposite by double-step mechanical alloying, Journal of Materials Science 44(10) (2009) 2566-2572. ##[34] L. Lu, M.O. Lai, F.L. Chen, Al-4 wt% Cu Composite reinforced with in-situ TiB2 particles, Acta Materialia 45(10) (1997) 4297-4309. ##[35] H.B. Michael Rajan, S. Ramabalan, I. Dinaharan, S.J. Vijay, Synthesis and characterization of in situ formed titanium diboride particulate reinforced AA7075 aluminum alloy cast composites, Materials and Design 44 (2013) 438-445. ##[36] M. Huang, X. Li, H. Yi, N. Ma, H. Wang, Effect of in situ TiB2 particle reinforcement on the creep resistance of hypoeutectic Al–12Si alloy, Journal of alloys and compounds 389(1-2) (2005) 275-280. ##[37] P.L. Schaffer, L. Arnberg, A.K. Dahle, Segregation of particles and its influence on the morphology of the eutectic silicon phase in Al–7 wt.% Si alloys, Scripta materialia 54(4) (2006) 677-682. ##[38] J. Wood, P. Davies, J. Kellie, Properties of reactively cast aluminium–TiB2 alloys, Materials science and technology 9(10) (1993) 833-840. ##[39] M. Zhao, G. Wu, L. Jiang, Z. Dou, Friction and wear properties of TiB2P/Al composite, Composites Part A: Applied Science and Manufacturing 37(11) (2006) 1916-1921. ##[40] A.P. Rao, K. Das, B. Murty, M. Chakraborty, Effect of grain refinement on wear properties of Al and Al–7Si alloy, Wear 257(1-2) (2004) 148-153. ##[41] M. Behpour, S. Ghoreishi, M. Khayatkashani, N. Soltani, The effect of two oleo-gum resin exudate from Ferula assa-foetida and Dorema ammoniacum on mild steel corrosion in acidic media, Corrosion science 53(8) (2011) 2489-2501. ##[42] M.F. Heragh, S. Eskandarinezhad, A. Dehghan, Ni-Cu matrix composite reinforced with CNTs: preparation, characterization, wear and corrosion behavior, inhibitory effects, Journal of Composites and Compounds 2(4) (2020) 123-128. ##[43] M.F. 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) 1-10. ##[44] A. Satapathy, G. Gunasekaran, S. Sahoo, K. Amit, P. Rodrigues, Corrosion inhibition by Justicia gendarussa plant extract in hydrochloric acid solution, Corrosion science 51(12) (2009) 2848-2856.</REF>
					</REFRENCE>
				</REFRENCES>
			</ARTICLE>
			<ARTICLE>
				<LANGUAGE_ID>1</LANGUAGE_ID>
				<TitleF>-</TitleF>
				<TitleE>ISynthesis and mechanical properties of Bi2O3-Al4Bi2O9 nanopowders</TitleE>
				<URL>https://jourcc.com/index.php/jourcc/article/view/jcc242</URL>
				<DOI>10.29252/jcc.2.4.2</DOI>
				<DOR/>
				<ABSTRACTS>
					<ABSTRACT>
						<LANGUAGE_ID>1</LANGUAGE_ID>
						<CONTENT>As a result of great surface area and a great number of energetic sites, ceramic nanocomposites are being considered as good adsorbents and catalysts. Al2O3 nanoparticles are widely used in high-tech applications owing to their excellent properties. Besides, Bi-based oxides have been the center of attention for applications such as remediation of hazardous wastes and wastewater photochemical degradation of organic contaminants and remediation of hazardous wastes. In this research, the synthesis of Bi2O3-Al4Bi2O9 nanocomposite and its mechanical properties as a novel composition were investigated. The results showed that the prepared Bi2O3-Al4Bi2O9 sample exhibited the Al4Bi2O9 crystalline peaks. Additionally, the prepared nanocomposite showed no impurities. The mechanical properties of the Bi2O3-Al4Bi2O9 sample were improved in comparison with Al2O3, Bi2O3, and Bi2O3- Al2O3, which offer it as a promising alternative to Bi2O3-Al2O3 composite ceramic.</CONTENT>
					</ABSTRACT>
					<ABSTRACT>
						<LANGUAGE_ID>0</LANGUAGE_ID>
						<CONTENT>-</CONTENT>
					</ABSTRACT>
				</ABSTRACTS>
				<PAGES>
					<PAGE>
						<FPAGE>171</FPAGE>
						<TPAGE>174</TPAGE>
					</PAGE>
				</PAGES>

				<AUTHORS>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Shayan</NameE>
						<MidNameE/>
						<FamilyE>Askari</FamilyE>
						<Organizations>
							<Organization>Department of Chemistry, Najafabad Branch, Islamic Azad University</Organization>
						</Organizations>
						<Countries>
							<Country>Iran</Country>
						</Countries>
						<EMAILS>
							<Email>shayan_askari@ymail.com</Email>
						</EMAILS>
					</AUTHOR>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Majid</NameE>
						<MidNameE/>
						<FamilyE>Ghashang</FamilyE>
						<Organizations>
							<Organization>Department of Chemistry, Najafabad 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>Ghazal</NameE>
						<MidNameE/>
						<FamilyE>Sohrabi</FamilyE>
						<Organizations>
							<Organization>Department of Chemistry, Najafabad Branch, Islamic Azad University</Organization>
						</Organizations>
						<Countries>
							<Country>Iran</Country>
						</Countries>
						<EMAILS>
							<Email>info@jourcc.com</Email>
						</EMAILS>
					</AUTHOR>
				</AUTHORS>
				<KEYWORDS>
					<KEYWORD>
						<KeyText>Nanocomposite</KeyText>
					</KEYWORD>
					<KEYWORD>
						<KeyText>Catalyst</KeyText>
					</KEYWORD>
					<KEYWORD>
						<KeyText>Al2O3</KeyText>
					</KEYWORD>
					<KEYWORD>
						<KeyText>Bi2O3-Al4Bi2O9</KeyText>
					</KEYWORD>
					<KEYWORD>
						<KeyText>Novel composition</KeyText>
					</KEYWORD>
				</KEYWORDS>
				<REFRENCES>
					<REFRENCE>
						<REF>[1] 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. ##[2] 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. ##[3] E. Thostenson, C. Li, T. Chou, Nanocomposites in context, Composites Science and Technology 65(3-4) (2005) 491-516. ##[4] F. Hussain, M. Hojjati, M. Okamoto, R.E. Gorga, Review article: Polymer-matrix Nanocomposites, Processing, Manufacturing, and Application: An Overview, Journal of Composite Materials 40(17) (2006) 1511-1575. ##[5] 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. ##[6] J.R. Gaudet, A. de la Riva, E.J. Peterson, T. Bolin, A.K. Datye, Improved Low-Temperature CO Oxidation Performance of Pd Supported on La-Stabilized Alumina, ACS Catalysis 3(5) (2013) 846-855. ##[7] H. Purón, J.L. Pinilla, C. Berrueco, J.A. Montoya de la Fuente, M. Millán, Hydrocracking of Maya Vacuum Residue with NiMo Catalysts Supported on Mesoporous Alumina and Silica–Alumina, Energy and Fuels 27(7) (2013) 3952-3960. ##[8] M.M. Ibrahim, Cr2O3/Al2O3 as adsorbent: Physicochemical properties and adsorption behaviors towards removal of Congo red dye from water, Journal of Environmental Chemical Engineering 7(1) (2019) 102848. ##[9] L.M. Camacho, A. Torres, D. Saha, S. Deng, Adsorption equilibrium and kinetics of fluoride on sol–gel-derived activated alumina adsorbents, Journal of Colloid and Interface Science 349(1) (2010) 307-313. ##[10] J. Li, L. Xu, P. Sun, P. Zhai, X. Chen, H. Zhang, Z. Zhang, W. Zhu, Novel application of red mud: Facile hydrothermal-thermal conversion synthesis of hierarchical porous AlOOH and Al2O3 microspheres as adsorbents for dye removal, Chemical Engineering Journal 321 (2017) 622-634. ##[11] K. Yang, Y. Li, Z. Zhao, Z. Tian, Y. Lai, Amorphous porous layered-Al2O3 derived from AlFu MOFs as an adsorbent for removing fluorine ions in industrial ZnSO4 solution, Chemical Engineering Research and Design 153 (2020) 562-571. ##[12] A. Khaleel, P.N. Kapoor, K.J. Klabunde, Nanocrystalline metal oxides as new adsorbents for air purification, Nanostructured Materials 11(4) (1999) 459-468. ##[13] K. Hristovski, A. Baumgardner, P. 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Arabsarhangi, Solution combustion synthesis using Schiff-base aluminum complex without fuel and optical property investigations of alumina nanoparticles, International Nano Letters 5(3) (2015) 141-146. ##[18] M. Hakimi, M. Morvaridi, H.A. Hosseini, P. Alimard, Preparation, characterization, and photocatalytic activity of Bi2O3–Al2O3 nanocomposite, Polyhedron 170 (2019) 523-529. ##[19] Z.N. Adamian, H.V. Abovian, V.M. Aroutiounian, Smoke sensor on the base of Bi2O3 sesquioxide, Sensors and Actuators B: Chemical 35(1) (1996) 241-243. ##[20] L. Leontie, M. Caraman, M. Alexe, C. Harnagea, Structural and optical characteristics of bismuth oxide thin films, Surface Science 507-510 (2002) 480-485. ##[21] L. Leontie, M. Caraman, M. Delibaş, G.I. Rusu, Optical properties of bismuth trioxide thin films, Materials Research Bulletin 36(9) (2001) 1629-1637. ##[22] V. Fruth, M. Popa, D. Berger, R. Ramer, M. Gartner, A. Ciulei, M. Zaharescu, Deposition and characterisation of bismuth oxide thin films, Journal of the European Ceramic Society 25(12) (2005) 2171-2174. ##[23] D. Kulkarni, I.E. Wachs, Isopropanol oxidation by pure metal oxide catalysts: number of active surface sites and turnover frequencies, Applied Catalysis A: General 237(1) (2002) 121-137. ##[24] T.-K. Tseng, J. Choi, D.-W. Jung, M. Davidson, P.H. Holloway, Three-Dimensional Self-Assembled Hierarchical Architectures of Gamma-Phase Flowerlike Bismuth Oxide, ACS Applied Materials and Interfaces 2(4) (2010) 943-946. ##[25] B. Yang, M. Mo, H. Hu, C. Li, X. Yang, Q. Li, Y. Qian, A Rational Self-Sacrificing Template Route to β-Bi2O3 Nanotube Arrays, European Journal of Inorganic Chemistry 2004(9) (2004) 1785-1787. ##[26] K. Karthik, K.S. Devi, D. Pinheiro, S. Sugunan, Influence of surfactant on the phase transformation of Bi2O3 and its photocatalytic activity, Australian Journal of Chemistry 72(4) (2019) 295-304. ##[27] M. Al-Buriahi, F. El-Agawany, C. Sriwunkum, H. Akyıldırım, H. Arslan, B. Tonguc, R. El-Mallawany, Y. Rammah, Influence of Bi2O3/PbO on nuclear shielding characteristics of lead-zinc-tellurite glasses, Physica B: Condensed Matter 581 (2020) 411946. ##[28] M.K. Trivedi, R.M. Tallapragada, A. Branton, D. Trivedi, G. Nayak, O. Latiyal, S. Jana, Evaluation of atomic, physical, and thermal properties of bismuth oxide powder: An impact of biofield energy treatment, (2015). ##[29] S. Thakur, V. Thakur, A. Kaur, L. Singh, Synthesis and the study of structural, thermal and optical properties of (100-x) Bi2O3-x (BaO-TiO2) glass system, Optik 223 (2020) 165646. ##[30] B.-H. Yun, Study on Bismuth-based Oxide Ion Conductors with High Performance and Durability for Lower Temperature Solid Oxide Fuel Cells, DGIST, 2020. ##[31] O.B. Dehkordi, A.M. Hadian, Joining of Alumina to Alumina Using Bismuth Oxide Nano Powder, Procedia Materials Science 11 (2015) 733-737. ##[32] K. Kohama, Joining of alumina ceramics using silicon–magnesium composite filler for high-temperature applications, Science and Technology of Welding and Joining 25(5) (2020) 383-390. ##[33] F. Cui, Z. Xu, R. Chu, X. He, X. Guo, G. Li, Low temperature sintering ZnO-Bi2O3 based varistor ceramics with low electrical breakdown voltage and high nonlinear coefficient, Ceramics International (2020). ##[34] Y. Liao, Y. Wang, Z. Chen, X. Wang, J. Li, R. Guo, C. Liu, G. Gan, G. Wang, Y. Li, Microstructure and enhanced magnetic properties of low-temperature sintered LiZnTiMn ferrite ceramics with Bi2O3-Al2O3 additive, Ceramics International 46(1) (2020) 487-492. ##[35] A.Y. Neiman, A.V. Tanskaya, E.V. Tsipis, L.M. Fyodorova, B.D. Antonov, Effect of size factor on mechanism of interaction between Al2O3 and Bi2O3 and conductivity of composite on their basis, Nanotechnologies in Russia 6(3-4) (2011) 218-226. ##[36] I. Zālīte, L. Grase, S. Lagzdina, D. Rašmane, Porous Ceramics from Al2O3 Nanopowders, Key Engineering Materials 850 (2020) 273-278. ##[37] S.K. Shubham, R. Purohit, P. Yadav, R. Rana, Study of nano-fillers embedded in polymer matrix composites to enhance its properties–A review, Materials Today: Proceedings (2020). ##[38] Y. Dong, A. Ma, D. Zhang, Y. Gao, H. Li, Preparation of high-performance α-Bi2O3 photocatalysts and their photocatalytic activity, Surface Innovations (2020) 1-9. ##[39] V. Amendola, I.D. Amans, Y. Ishikawa, N. Koshizaki, S. Scirè, G. Compagnini, S. Reichenberger, I.S. Barcikowski, Room‐Temperature Laser Synthesis in Liquid of Oxide, Metal‐Oxide Core‐Shells, and Doped Oxide Nanoparticles, Chemistry (Weinheim an der Bergstrasse, Germany) 26(42) (2020) 9206. ##[40] M. Parashar, V.K. Shukla, R. Singh, Metal oxides nanoparticles via sol–gel method: a review on synthesis, characterization and applications, Journal of Materials Science: Materials in Electronics (2020) 1-21. ##[41] P. Karasiński, A. Domanowska, E. Gondek, A. Sikora, C. Tyszkiewicz, M. Skolik, Homogeneity of sol-gel derived silica-titania waveguide films–Spectroscopic and AFM studies, Optics and Laser Technology 121 (2020) 105840. ##[42] H. Ibrahimov, L. Afandiyeva, S. Malikli, G. Rustamli, R. Babali, Obtaining of nanostructured γ-Al2O3 by sol-gel method, Thermam (2020) 83. ##[43] 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). ##[44] A. Masoudian, M. Karbasi, F. SharifianJazi, A. Saidi, Developing Al2O3-TiC in-situ nanocomposite by SHS and analyzingtheeffects of Al content and mechanical activation on microstructure, Journal of Ceramic Processing Research 14(4) (2013) 486-491. ##[45] 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.##</REF>
					</REFRENCE>
				</REFRENCES>
			</ARTICLE>
			<ARTICLE>
				<LANGUAGE_ID>1</LANGUAGE_ID>
				<TitleF>-</TitleF>
				<TitleE>Thermal conductivity, viscosity and heat transfer process in nanofluids: A critical review</TitleE>
				<URL>https://www.jourcc.com/index.php/jourcc/article/view/jcc243</URL>
				<DOI>10.29252/jcc.2.4.3</DOI>
				<DOR/>
				<ABSTRACTS>
					<ABSTRACT>
						<LANGUAGE_ID>1</LANGUAGE_ID>
						<CONTENT>‎Heat transfer efficiency has always been at the center of attractions for many researchers and industries and demand for higher efficiency methods and materials are increased in the last decades. One of the effective methods to enhance the thermal performance of instruments is using nanofluids as a solid-liquid suspension.  In the present paper, the thermal conductivity, viscosity, and heat transfer process of the nanofluids are discussed. The effect of volume fraction, temperature, particle size, shape, base fluid type, and other factors on thermal conductivity, viscosity, and convective heat transfer coefficient of nanofluids are presented. Also, the preparation methods of nanofluids are exhibited and the stability and the effective factors on the stability of nanofluids are brought in the manuscript. Besides, a summarized number of experimental and mathematical studies about the thermal conductivity, viscosity, and stability of nanofluids are listed, compared, and analyzed. The works about the Nusselt number in fluids and nanofluids are presented in detail to determine the future challenges of nanofluids.</CONTENT>
					</ABSTRACT>
					<ABSTRACT>
						<LANGUAGE_ID>0</LANGUAGE_ID>
						<CONTENT>-</CONTENT>
					</ABSTRACT>
				</ABSTRACTS>
				<PAGES>
					<PAGE>
						<FPAGE>175</FPAGE>
						<TPAGE>192</TPAGE>
					</PAGE>
				</PAGES>

				<AUTHORS>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Saeed</NameE>
						<MidNameE/>
						<FamilyE>Noorzadeh</FamilyE>
						<Organizations>
							<Organization>Department of Mechanical Engineering, University of Mohaghegh Ardabili</Organization>
						</Organizations>
						<Countries>
							<Country>Iran</Country>
						</Countries>
						<EMAILS>
							<Email>info@jourcc.com</Email>
						</EMAILS>
					</AUTHOR>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Farhad</NameE>
						<MidNameE/>
						<FamilyE>Sadegh Moghanlou</FamilyE>
						<Organizations>
							<Organization>Department of Mechanical Engineering, University of Mohaghegh Ardabili</Organization>
						</Organizations>
						<Countries>
							<Country>Iran</Country>
						</Countries>
						<EMAILS>
							<Email>f_moghanlou@uma.ac.ir</Email>
						</EMAILS>
					</AUTHOR>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Mohammad</NameE>
						<MidNameE/>
						<FamilyE>Vajdi</FamilyE>
						<Organizations>
							<Organization>Department of Mechanical Engineering, University of Mohaghegh Ardabili</Organization>
						</Organizations>
						<Countries>
							<Country>Iran</Country>
						</Countries>
						<EMAILS>
							<Email>info@jourcc.com</Email>
						</EMAILS>
					</AUTHOR>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Mohammad</NameE>
						<MidNameE/>
						<FamilyE>Ataei</FamilyE>
						<Organizations>
							<Organization>Department of Mechanical Engineering, University of Mohaghegh Ardabili</Organization>
						</Organizations>
						<Countries>
							<Country>Iran</Country>
						</Countries>
						<EMAILS>
							<Email>info@jourcc.com</Email>
						</EMAILS>
					</AUTHOR>
				</AUTHORS>
				<KEYWORDS>
					<KEYWORD>
						<KeyText>Nanofluid</KeyText>
					</KEYWORD>
					<KEYWORD>
						<KeyText>Heat transfer</KeyText>
					</KEYWORD>
					<KEYWORD>
						<KeyText>Thermal conductivity</KeyText>
					</KEYWORD>
					<KEYWORD>
						<KeyText>Convection</KeyText>
					</KEYWORD>
				</KEYWORDS>
				<REFRENCES>
					<REFRENCE>
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Yekani, S., Abdi Aghdam, E., Sadegh Moghanlo, Experimental study of The Performance and e xhaust gas emissions Response of A Spark Ignition Engine to Adding Natural Gas to Gasoline in CR=11., Int. J. Ind. Math. 11 (2019) 307–317. ##[6] T. Gholizadeh, M. Vajdi, H. Rostamzadeh, Energy and exergy evaluation of a new bi-evaporator electricity/cooling cogeneration system fueled by biogas, J. Clean. Prod. 233 (2019) 1494–1509. doi:10.1016/j.jclepro.2019.06.086. ##[7] T. Gholizadeh, M. Vajdi, H. Rostamzadeh, Exergoeconomic optimization of a new trigeneration system driven by biogas for power, cooling, and freshwater production, Energy Convers. Manag. 205 (2020) 112417. doi:10.1016/j.enconman.2019.112417. ##[8] S.M.F. Yekani S, Abdi Aghdam E, Performance Response of a Spark Ignition Engine to Adding Natural Gas to Gasoline on Lean-Burn Condition in 10 Compression Ratio., Modares Mech. Eng. 20 (2020) 1691–1699. ##[9] M. Namazizadeh, M. Talebian Gevari, M. Mojaddam, M. Vajdi, Optimization of the Splitter Blade Configuration and Geometry of a Centrifugal Pump Impeller using Design of Experiment, J. Appl. Fluid Mech. 13 (2020) 89–101. doi:10.29252/jafm.13.01.29856. ##[10] F.S. Moghanlou, A.S. Khorrami, E. Esmaeilzadeh, H. Aminfar, Experimental study on electrohydrodynamically induced heat transfer enhancement in a minichannel, Exp. Therm. Fluid Sci. 59 (2014) 24–31. doi:10.1016/j.expthermflusci.2014.07.019. ##[11] R.L. Webb, N.-H. Kim, principles enhanced heat transfer, CRC Press, 2005. ##[12] J.S. Moghanlou FS, Ghazanfari Jajin E, Vajdy Hokmabad M, On the Experimental and Numerical Droplet Generation in the Ordinary and Modified Micro channels with Oval Obstacle, Modares Mech. Eng. 20 (2020). ##[13] Y. Sui, P.S. Lee, C.J. Teo, An experimental study of flow friction and heat transfer in wavy microchannels with rectangular cross section, Int. J. Therm. Sci. 50 (2011) 2473–2482. doi:10.1016/j.ijthermalsci.2011.06.017. ##[14] M. Shahedi Asl, M. 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Conduct. Fluids with Nanoparticles, n.d.: pp. 99–106. ##[23] W.H. Choi S. Siginer DA, Developments and Applications of Non-Newtonian Flows, 1995. ##[24] M. Ataei, F. Sadegh Moghanlou, S. Noorzadeh, M. Vajdi, M. Shahedi Asl, Heat transfer and flow characteristics of hybrid Al2O3/TiO2–water nanofluid in a minichannel heat sink, Heat Mass Transf. 56 (2020) 2757–2767. doi:10.1007/s00231-020-02896-9. ##[25] S. Chakraborty, An investigation on the long-term stability of TiO2 nanofluid, Mater. Today Proc. 11 (2019) 714–718. doi:10.1016/j.matpr.2019.03.032. ##[26] H. Zhang, S. Wang, Y. Lin, M. Feng, Q. Wu, Stability, thermal conductivity, and rheological properties of controlled reduced graphene oxide dispersed nanofluids, Appl. Therm. Eng. 119 (2017) 132–139. doi:10.1016/j.applthermaleng.2017.03.064. ##[27] W. Yu, D.M. France, S.U.S. Choi, J.L. Routbort, Review and assessment of nanofluid technology for transportation and other applications., Argonne, IL, 2007. doi:10.2172/919327. ##[28] C.G. Granqvist, R.A. Buhrman, J. Wyns, A.J. Sievers, Far-Infrared Absorption in Ultrafine Al Particles, Phys. Rev. Lett. 37 (1976) 625–629. doi:10.1103/PhysRevLett.37.625. ##[29] J.-H. Lee, K.S. Hwang, S.P. Jang, B.H. Lee, J.H. Kim, S.U.S. Choi, C.J. Choi, Effective viscosities and thermal conductivities of aqueous nanofluids containing low volume concentrations of Al2O3 nanoparticles, Int. J. Heat Mass Transf. 51 (2008) 2651–2656. doi:10.1016/j.ijheatmasstransfer.2007.10.026. ##[30] J.A. Eastman, S.U.S. Choi, S. Li, W. Yu, L.J. Thompson, Anomalously increased effective thermal conductivities of ethylene glycol-based nanofluids containing copper nanoparticles, Appl. Phys. Lett. 78 (2001) 718–720. doi:10.1063/1.1341218. ##[31] W. Yu, H. Xie, L. Chen, Y. Li, Investigation of thermal conductivity and viscosity of ethylene glycol based ZnO nanofluid, Thermochim. Acta. 491 (2009) 92–96. doi:10.1016/j.tca.2009.03.007. ##[32] Y. Hwang, J.K. Lee, C.H. Lee, Y.M. Jung, S.I. Cheong, C.G. Lee, B.C. Ku, S.P. Jang, Stability and thermal conductivity characteristics of nanofluids, Thermochim. Acta. 455 (2007) 70–74. doi:10.1016/j.tca.2006.11.036. ##[33] M.A. Khairul, K. Shah, E. Doroodchi, R. Azizian, B. Moghtaderi, Effects of surfactant on stability and thermo-physical properties of metal oxide nanofluids, Int. J. Heat Mass Transf. 98 (2016) 778–787. doi:10.1016/j.ijheatmasstransfer.2016.03.079. ##[34] V. Fuskele, R.M. Sarviya, Recent developments in Nanoparticles Synthesis, Preparation and Stability of Nanofluids, Mater. Today Proc. 4 (2017) 4049–4060. doi:10.1016/j.matpr.2017.02.307. ##[35] A. Ghadimi, R. Saidur, H.S.C. Metselaar, A review of nanofluid stability properties and characterization in stationary conditions, Int. J. Heat Mass Transf. 54 (2011) 4051–4068. doi:10.1016/j.ijheatmasstransfer.2011.04.014. ##[36] M. Sakkaki, F. Sadegh Moghanlou, M. Vajdi, M. Shahedi Asl, M. Mohammadi, M. Shokouhimehr, Numerical simulation of heat transfer during spark plasma sintering of zirconium diboride, Ceram. Int. 46 (2020) 4998–5007. doi:10.1016/j.ceramint.2019.10.240. ##[37] F. Sadegh Moghanlou, M. Vajdi, J. Sha, A. Motallebzadeh, M. Shokouhimehr, M. Shahedi Asl, A numerical approach to the heat transfer in monolithic and SiC reinforced HfB. ##</REF>
					</REFRENCE>
				</REFRENCES>
			</ARTICLE>
			<ARTICLE>
				<LANGUAGE_ID>1</LANGUAGE_ID>
				<TitleF>-</TitleF>
				<TitleE>An overview of the development of composites containing Mg and Zn for drug delivery</TitleE>
				<URL>https://www.jourcc.com/index.php/jourcc/article/view/jcc244</URL>
				<DOI>10.29252/jcc.2.4.4</DOI>
				<DOR/>
				<ABSTRACTS>
					<ABSTRACT>
						<LANGUAGE_ID>1</LANGUAGE_ID>
						<CONTENT>Drug delivery is known as the administration of drugs using suitable vehicle for achieving effective treatment with no unwanted effects. In recent years, various composite materials have been developed and evaluated for being used in different biomedical fields such as wound dressings, cardiac prosthesis, tissue engineering, and drug delivery. Zinc is the second most available element after Fe in our body. Nanoparticles based on metal oxides, such as zinc oxides and Zn-containing composites, can be considered as viable platforms for some biomedical uses, especially for drug delivery applications. Mg composite biomaterials are also suggested for diverse biomedical applications due to their good mechanical properties, biocompatibility, and bioactivity. This paper highlights applications of zinc and magnesium-based composites in development of drug delivery systems.</CONTENT>
					</ABSTRACT>
					<ABSTRACT>
						<LANGUAGE_ID>0</LANGUAGE_ID>
						<CONTENT>-</CONTENT>
					</ABSTRACT>
				</ABSTRACTS>
				<PAGES>
					<PAGE>
						<FPAGE>193</FPAGE>
						<TPAGE>204</TPAGE>
					</PAGE>
				</PAGES>

				<AUTHORS>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Firooze</NameE>
						<MidNameE/>
						<FamilyE>Niazvand</FamilyE>
						<Organizations>
							<Organization>School of Medicine, Abadan Faculty of Medical Sciences</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>amir_cheshomi@yahoo.com</Email>
						</EMAILS>
					</AUTHOR>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Maryam</NameE>
						<MidNameE/>
						<FamilyE>Zand</FamilyE>
						<Organizations>
							<Organization>Department of Physics, Alzahra University</Organization>
						</Organizations>
						<Countries>
							<Country>Iran</Country>
						</Countries>
						<EMAILS>
							<Email>info@jourcc.com</Email>
						</EMAILS>
					</AUTHOR>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Reyhaneh</NameE>
						<MidNameE/>
						<FamilyE>Nasr Azadani</FamilyE>
						<Organizations>
							<Organization>Department of Biomaterials Nanotechnology and Tissue engineering, Isfahan University of Medical Sciences</Organization>
						</Organizations>
						<Countries>
							<Country>Iran</Country>
						</Countries>
						<EMAILS>
							<Email>info@jourcc.com</Email>
						</EMAILS>
					</AUTHOR>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Beena</NameE>
						<MidNameE/>
						<FamilyE>Kumari</FamilyE>
						<Organizations>
							<Organization>Department of Pharmaceutical Sciences, Indira Gandhi University</Organization>
						</Organizations>
						<Countries>
							<Country>India</Country>
						</Countries>
						<EMAILS>
							<Email>info@jourcc.com</Email>
						</EMAILS>
					</AUTHOR>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Ali</NameE>
						<MidNameE/>
						<FamilyE>Raza</FamilyE>
						<Organizations>
							<Organization>School of Biomedical Engineering, Shanghai Jiaotong University</Organization>
						</Organizations>
						<Countries>
							<Country>China</Country>
						</Countries>
						<EMAILS>
							<Email>info@jourcc.com</Email>
						</EMAILS>
					</AUTHOR>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Shima</NameE>
						<MidNameE/>
						<FamilyE>Nasibi</FamilyE>
						<Organizations>
							<Organization>Materials Science and Engineering Department, Shiraz University</Organization>
						</Organizations>
						<Countries>
							<Country>Iran</Country>
						</Countries>
						<EMAILS>
							<Email>info@jourcc.com</Email>
						</EMAILS>
					</AUTHOR>
				</AUTHORS>
				<KEYWORDS>
					<KEYWORD>
						<KeyText>Drug delivery</KeyText>
					</KEYWORD>
					<KEYWORD>
						<KeyText>Biomedical application</KeyText>
					</KEYWORD>
					<KEYWORD>
						<KeyText>Zinc oxide composite</KeyText>
					</KEYWORD>
					<KEYWORD>
						<KeyText>Mg composites</KeyText>
					</KEYWORD>
				</KEYWORDS>
				<REFRENCES>
					<REFRENCE>
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					</REFRENCE>
				</REFRENCES>
			</ARTICLE>
			<ARTICLE>
				<LANGUAGE_ID>1</LANGUAGE_ID>
				<TitleF>-</TitleF>
				<TitleE>Recent progress in materials used towards corrosion protection of Mg and its alloys</TitleE>
				<URL>https://www.jourcc.com/index.php/jourcc/article/view/jcc245</URL>
				<DOI>10.29252/jcc.2.4.5</DOI>
				<DOR/>
				<ABSTRACTS>
					<ABSTRACT>
						<LANGUAGE_ID>1</LANGUAGE_ID>
						<CONTENT>Magnesium has little resistance to corrosion and therefore its production and use are quite limited. The problem of corrosion associated with these alloys has been alleviated to some extent by the advantages obtained from fine coatings. An additional dense barrier against corrosion is created, using coatings obtained from sol-gel. As an alternative for Cr-based conversion coatings, rare-earth elements-based ones are been increasingly investigated for Mg and its alloys due to being eco-friendly. Because of chemical inertness, low friction, and high hardness, diamond-like carbon (DLC) coatings have exhibited the best protection for Mg and its alloys. In this review, we shed light on recent advancements in novel coatings for Mg alloys including hybrid, rare-earth conversion, composite polymeric (polymer composite is a multi-phase material in which reinforcing fillers are integrated with a polymer matrix), and DLC coatings.</CONTENT>
					</ABSTRACT>
					<ABSTRACT>
						<LANGUAGE_ID>0</LANGUAGE_ID>
						<CONTENT>-</CONTENT>
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				</ABSTRACTS>
				<PAGES>
					<PAGE>
						<FPAGE>205</FPAGE>
						<TPAGE>214</TPAGE>
					</PAGE>
				</PAGES>

				<AUTHORS>
					<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>Saber</NameE>
						<MidNameE/>
						<FamilyE>Hasanizadeh</FamilyE>
						<Organizations>
							<Organization>Chemical Engineering Department, Kermanshah 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>Sara</NameE>
						<MidNameE/>
						<FamilyE>Eskandarinezhad</FamilyE>
						<Organizations>
							<Organization>Department of Mining and Metallurgy, Yazd University</Organization>
						</Organizations>
						<Countries>
							<Country>Iran</Country>
						</Countries>
						<EMAILS>
							<Email>info@jourcc.com</Email>
						</EMAILS>
					</AUTHOR>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Soheil</NameE>
						<MidNameE/>
						<FamilyE>Hassani</FamilyE>
						<Organizations>
							<Organization>Department of Materials Engineering, Science and Research 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>Mohsen</NameE>
						<MidNameE/>
						<FamilyE>Sheibani</FamilyE>
						<Organizations>
							<Organization>Department of Materials Engineering and Metallurgy, Shiraz 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>Alireza</NameE>
						<MidNameE/>
						<FamilyE>Dordsheikh Torkamani</FamilyE>
						<Organizations>
							<Organization>School of Metallurgy and Materials Engineering, Iran University of Science and Technology (IUST)</Organization>
						</Organizations>
						<Countries>
							<Country>Iran</Country>
						</Countries>
						<EMAILS>
							<Email>info@jourcc.com</Email>
						</EMAILS>
					</AUTHOR>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Belma</NameE>
						<MidNameE/>
						<FamilyE>Fakić</FamilyE>
						<Organizations>
							<Organization>Metallographic laboratory, Institute “Kemal Kapetanović” in Zenica, University of Zenica</Organization>
						</Organizations>
						<Countries>
							<Country>B and H</Country>
						</Countries>
						<EMAILS>
							<Email>info@jourcc.com</Email>
						</EMAILS>
					</AUTHOR>
				</AUTHORS>
				<KEYWORDS>
					<KEYWORD>
						<KeyText>Hybrid coatings</KeyText>
					</KEYWORD>
					<KEYWORD>
						<KeyText>Rare-earth</KeyText>
					</KEYWORD>
					<KEYWORD>
						<KeyText>Polymeric composite</KeyText>
					</KEYWORD>
					<KEYWORD>
						<KeyText>DLC coatings</KeyText>
					</KEYWORD>
				</KEYWORDS>
				<REFRENCES>
					<REFRENCE>
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					</REFRENCE>
				</REFRENCES>
			</ARTICLE>
			<ARTICLE>
				<LANGUAGE_ID>1</LANGUAGE_ID>
				<TitleF>-</TitleF>
				<TitleE>Nanodiamond-containing composites for tissue scaﬀolds and surgical implants: A review</TitleE>
				<URL>https://www.jourcc.com/index.php/jourcc/article/view/jcc246</URL>
				<DOI>10.29252/jcc.2.4.6</DOI>
				<DOR/>
				<ABSTRACTS>
					<ABSTRACT>
						<LANGUAGE_ID>1</LANGUAGE_ID>
						<CONTENT>Due to promising properties such as low toxicity against diﬀerent cell lines, being highly stable ﬂuorescent without showing photobleaching, and good surface properties, nanodiamonds have gained ever-increasing attention for various biomedical applications including bioimaging and therapeutic applications. Various methods are used for the fabrication of nanostructured diamond, the commonly used of which is the denotation technique. Newer approaches are being practiced for the modifcation and functionalization of their surfaces by diﬀerent biomolecules suitable for interaction with considered targets. In this review, the scope and recent advancement in the feld of nanodiamonds for biomedical applications particularly their application for nanocomposite scaﬀold and implants are discussed.</CONTENT>
					</ABSTRACT>
					<ABSTRACT>
						<LANGUAGE_ID>0</LANGUAGE_ID>
						<CONTENT>-</CONTENT>
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				<PAGES>
					<PAGE>
						<FPAGE>215</FPAGE>
						<TPAGE>227</TPAGE>
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				<AUTHORS>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Yasamin</NameE>
						<MidNameE/>
						<FamilyE>Zamani</FamilyE>
						<Organizations>
							<Organization>Department of Biology, Tehran Medical Sciences 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>Ali</NameE>
						<MidNameE/>
						<FamilyE>Zareein</FamilyE>
						<Organizations>
							<Organization>Department of Biomedical Engineering, Tabriz 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>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>Reyhaneh</NameE>
						<MidNameE/>
						<FamilyE>Nasr Azadani</FamilyE>
						<Organizations>
							<Organization>Department of Biomaterials Nanotechnology and Tissue engineering, Isfahan University of Medical Sciences</Organization>
						</Organizations>
						<Countries>
							<Country>Iran</Country>
						</Countries>
						<EMAILS>
							<Email>info@jourcc.com</Email>
						</EMAILS>
					</AUTHOR>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Babar</NameE>
						<MidNameE/>
						<FamilyE>Pasha Mahammod</FamilyE>
						<Organizations>
							<Organization>National Institute of Technology Warangal</Organization>
						</Organizations>
						<Countries>
							<Country>India</Country>
						</Countries>
						<EMAILS>
							<Email>info@jourcc.com</Email>
						</EMAILS>
					</AUTHOR>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Shima</NameE>
						<MidNameE/>
						<FamilyE>Nasibi</FamilyE>
						<Organizations>
							<Organization>Department of Materials Science and Engineering, Shiraz 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>Integrative Medicine Cluster, Advanced Medical and Dental Institute, Universiti Sains Malaysia</Organization>
						</Organizations>
						<Countries>
							<Country>Malaysia</Country>
						</Countries>
						<EMAILS>
							<Email>amirmch@gmail.com</Email>
						</EMAILS>
					</AUTHOR>
				</AUTHORS>
				<KEYWORDS>
					<KEYWORD>
						<KeyText>Nanodiamonds</KeyText>
					</KEYWORD>
					<KEYWORD>
						<KeyText>Surface modifcation</KeyText>
					</KEYWORD>
					<KEYWORD>
						<KeyText>Biomedical application</KeyText>
					</KEYWORD>
					<KEYWORD>
						<KeyText>Nanocomposite scaﬀold</KeyText>
					</KEYWORD>
					<KEYWORD>
						<KeyText>Implants</KeyText>
					</KEYWORD>
				</KEYWORDS>
				<REFRENCES>
					<REFRENCE>
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					</REFRENCE>
				</REFRENCES>
			</ARTICLE>
			<ARTICLE>
				<LANGUAGE_ID>1</LANGUAGE_ID>
				<TitleF>-</TitleF>
				<TitleE>Application of composite conducting polymers for improving the corrosion behavior of various substrates: A Review</TitleE>
				<URL>https://www.jourcc.com/index.php/jourcc/article/view/jcc247</URL>
				<DOI>10.29252/jcc.2.4.7</DOI>
				<DOR/>
				<ABSTRACTS>
					<ABSTRACT>
						<LANGUAGE_ID>1</LANGUAGE_ID>
						<CONTENT>One of the most important problems in the manufacturing industry is metal corrosion. Recently, conductive polymers (CPs) have attracted attention due to their economic viability and widespread industrial applications. Upon adsorption, long-chain carbon bonds of polymers provide a blockage for large surface areas of corroding metals. The adsorbed thin films create a barrier between the surrounding environment and the metal substrate. Polypyrrole (PPy), polyaniline (PANI), and polythiophene (PTh) are conducting polymers that are utilized to protect metals and metal alloys against corrosion. A proper selection of synthesis parameters for CPs can improve the anticorrosion behavior of the coatings for metals and metal alloys. This paper has an overview of conducting polymer composite coatings on substrates based on steel, copper, magnesium, aluminum, and their alloys.</CONTENT>
					</ABSTRACT>
					<ABSTRACT>
						<LANGUAGE_ID>0</LANGUAGE_ID>
						<CONTENT>-</CONTENT>
					</ABSTRACT>
				</ABSTRACTS>
				<PAGES>
					<PAGE>
						<FPAGE>228</FPAGE>
						<TPAGE>240</TPAGE>
					</PAGE>
				</PAGES>

				<AUTHORS>
					<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>leilabazli64@gmail.com</Email>
						</EMAILS>
					</AUTHOR>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Mohammad</NameE>
						<MidNameE/>
						<FamilyE>Yusuf</FamilyE>
						<Organizations>
							<Organization>Department of Chemical Engineering, Universiti Teknologi PETRONAS</Organization>
						</Organizations>
						<Countries>
							<Country>Malaysia</Country>
						</Countries>
						<EMAILS>
							<Email>info@jourcc.com</Email>
						</EMAILS>
					</AUTHOR>
					<AUTHOR>
						<Name>-</Name>
						<MidName/>
						<Family>-</Family>
						<NameE>Ali</NameE>
						<MidNameE/>
						<FamilyE>Farahani</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>Morvarid</NameE>
						<MidNameE/>
						<FamilyE>Kiamarzi</FamilyE>
						<Organizations>
							<Organization>Department of Polymer Engineering and Color Technology, 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>Zahra</NameE>
						<MidNameE/>
						<FamilyE>Seyedhosseini</FamilyE>
						<Organizations>
							<Organization>Department of Chemistry, 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>Mehran</NameE>
						<MidNameE/>
						<FamilyE>Nezhadmansari</FamilyE>
						<Organizations>
							<Organization>Department of Engineering and Materials Science, Sharif 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>Aliasghari</FamilyE>
						<Organizations>
							<Organization>Department of Chemistry, Yadegar-e-Imam Khomeini (RAH) Shahre 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>Marjan</NameE>
						<MidNameE/>
						<FamilyE>Iranpoor</FamilyE>
						<Organizations>
							<Organization>Department of Agricultural Machinery Mechanics, University of Tehran</Organization>
						</Organizations>
						<Countries>
							<Country>Iran</Country>
						</Countries>
						<EMAILS>
							<Email>info@jourcc.com</Email>
						</EMAILS>
					</AUTHOR>
				</AUTHORS>
				<KEYWORDS>
					<KEYWORD>
						<KeyText>Corrosion resistance</KeyText>
					</KEYWORD>
					<KEYWORD>
						<KeyText>Polyaniline</KeyText>
					</KEYWORD>
					<KEYWORD>
						<KeyText>Polypyrrole</KeyText>
					</KEYWORD>
					<KEYWORD>
						<KeyText>Polythiophene</KeyText>
					</KEYWORD>
					<KEYWORD>
						<KeyText>Metal substrates</KeyText>
					</KEYWORD>
				</KEYWORDS>
				<REFRENCES>
					<REFRENCE>
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