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Online since: September 2015
Authors: Reshmi Dey, Pranjali Nanda, Arunachalam Thirugnanam
Introduction
Pure titanium (Ti) and its alloys are biologically inert materials capable of self-passivation are the best implant option for load bearing sites due to high strength to weight ratio, low density, low modulus and excellent biocompatibility.
Materials and Methods Titanium sponge (Fe 0.024%, Cl 0.046%, N 0.006%, O 0.026%, Si 0.002, Ni 0.013%, C 0.005%, Mg 0.018%, balance Ti) obtained from MIDHANI, Hyderabad were subjected to chemical modifications as shown in Table 1 and coded accordingly.
Brinson, Mechanics considerations for microporous titanium as an orthopedic implant material, Journal of Biomedical Materials Research Part A. 69(4) (2004) 601-610
Nakamura, Preparation of bioactive Ti and its alloys via simple chemical surface treatment, Journal of biomedical materials research. 32(3) (1996) 409-417
Horiuchi, Protein adsorption properties on titanium with and without calcium titanate-coating, Materials Science and Engineering 18 (2011) 192023
Materials and Methods Titanium sponge (Fe 0.024%, Cl 0.046%, N 0.006%, O 0.026%, Si 0.002, Ni 0.013%, C 0.005%, Mg 0.018%, balance Ti) obtained from MIDHANI, Hyderabad were subjected to chemical modifications as shown in Table 1 and coded accordingly.
Brinson, Mechanics considerations for microporous titanium as an orthopedic implant material, Journal of Biomedical Materials Research Part A. 69(4) (2004) 601-610
Nakamura, Preparation of bioactive Ti and its alloys via simple chemical surface treatment, Journal of biomedical materials research. 32(3) (1996) 409-417
Horiuchi, Protein adsorption properties on titanium with and without calcium titanate-coating, Materials Science and Engineering 18 (2011) 192023
Online since: June 2022
Authors: Jinesh Kumar Jain, Pankaj Sonia, Kahtan A. Mohammed
These materials in the pure form not having a desired characteristics like biodegradation rate and mechanical properties.
Reinbolt, “Friction stir processing of particle reinforced composite materials,” Materials (Basel)., 3:(1) (2010) 329-350
Suryanarayana, “Mechanical Alloying: A Novel Technique to Synthesize Advanced Materials,” Research, 2019 (2019) 17
Grant, “Spray forming,” Progress in Materials Science. 39 (1995) 497-545 [49] G.S.E.
Wong, “Magnesium-based nanocomposites: Lightweight materials of the future,” Materials Characterization. 105 (2015) 30-46
Reinbolt, “Friction stir processing of particle reinforced composite materials,” Materials (Basel)., 3:(1) (2010) 329-350
Suryanarayana, “Mechanical Alloying: A Novel Technique to Synthesize Advanced Materials,” Research, 2019 (2019) 17
Grant, “Spray forming,” Progress in Materials Science. 39 (1995) 497-545 [49] G.S.E.
Wong, “Magnesium-based nanocomposites: Lightweight materials of the future,” Materials Characterization. 105 (2015) 30-46
Online since: February 2024
Authors: Umi Shaffiqah Mohd Zubir, Sunarti Abd Rahman
To enhance the performances of membranes, polymeric materials and inorganic molecular sieves are combined to fabricate mixed matrix membranes.
Different materials or combinations of materials are selected to achieve the desired properties [3].
Materials and methods The materials were used in this experiment is Polyvinylidene Fluoride (PVDF) polymer (MW = 64.03 g/mol) with N-Methyl-2-pyrrolidone (NMP) (MW = 99.13 g/mol) as the solvent.
State-of-the-art of eggshell waste in materials science: recent advances in catalysis, pharmaceutical applications, and mechanochemistry.
In Journal of Industrial and Engineering Chemistry (Vol. 56, pp. 35–44).
Different materials or combinations of materials are selected to achieve the desired properties [3].
Materials and methods The materials were used in this experiment is Polyvinylidene Fluoride (PVDF) polymer (MW = 64.03 g/mol) with N-Methyl-2-pyrrolidone (NMP) (MW = 99.13 g/mol) as the solvent.
State-of-the-art of eggshell waste in materials science: recent advances in catalysis, pharmaceutical applications, and mechanochemistry.
In Journal of Industrial and Engineering Chemistry (Vol. 56, pp. 35–44).
Online since: January 2013
Authors: Hong Mei Zhang, Li Feng Qiao
The Development of Annealing time for Super Fine Grain and High Strength IF Steel
Hongmei Zhang1,a Li feng Qiao2,b
1University of Science and Technology Liaoning, Anshan, 114051, China
2An-Shan Iron & Steel Company Ltd An-ling Company, Liaoning, ChaoYang 122000, China
alilyzhm68@163.com
b15042888161@139.com
Keywords: super fine-high strength IF steel; continuous annealing; mechanical properties
Abstract.
Experimental Materials and Experimental Procedure Experimental Material The IF steel was melted in a 50-kg laboratory induction furnace and cast in situ, both under the protective atmosphere of Ar.
Fig.2 The effect of different annealing time on mechanical property of test steel Fig.3 The effect of different annealing time on n and r value of test steel (T=850℃, ε=80%) Acknowledgments The first author (Hong-Mei Zhang) would like to thank the financial support of Science and Technology Research Project Foundation of Department of Education of Liao-Ning province under Grant No.LS2010086 and Natural Science Foundation of Liao-Ning province under Grant No.20102099.
[6] H.Zhao, S.C.Rama, G.C.Bzrber, Z.Wang, X.Wang, Journal of Materials Processing Technology, Vol.5(2002),p1~7
Experimental Materials and Experimental Procedure Experimental Material The IF steel was melted in a 50-kg laboratory induction furnace and cast in situ, both under the protective atmosphere of Ar.
Fig.2 The effect of different annealing time on mechanical property of test steel Fig.3 The effect of different annealing time on n and r value of test steel (T=850℃, ε=80%) Acknowledgments The first author (Hong-Mei Zhang) would like to thank the financial support of Science and Technology Research Project Foundation of Department of Education of Liao-Ning province under Grant No.LS2010086 and Natural Science Foundation of Liao-Ning province under Grant No.20102099.
[6] H.Zhao, S.C.Rama, G.C.Bzrber, Z.Wang, X.Wang, Journal of Materials Processing Technology, Vol.5(2002),p1~7
Online since: February 2014
Authors: Da Li, Yan Ping Ren, Jia Meng Qin, Chun Li
In the area of the solidification of metallic materials, ultrasonic vibration can effectively grain-refine both aluminium and magnesium alloys[3,5].
Acknowledgements This work has been subsidized by the National Natural Science Foundation of China (Grant No. 51062015) and by the Jiangxi Provincial Natural Science Foundation, China (Grant No.
Hildebrand, Metallurgical and Materials Transactions A.
Kozawa, , International Journal of Heat and Mass Transfer.
Eskin, Ultrasonic Treatment of Light Alloy Melts (Amsterdam, Gordon and Breach Science Publishers, 1998), 155
Acknowledgements This work has been subsidized by the National Natural Science Foundation of China (Grant No. 51062015) and by the Jiangxi Provincial Natural Science Foundation, China (Grant No.
Hildebrand, Metallurgical and Materials Transactions A.
Kozawa, , International Journal of Heat and Mass Transfer.
Eskin, Ultrasonic Treatment of Light Alloy Melts (Amsterdam, Gordon and Breach Science Publishers, 1998), 155
Online since: November 2011
Authors: Jin Song Leng, Jian Sun, Yan Yi Xu, Yi Jin Chen, Yan Ju Liu
Box 3011, Centre for Composite Materials, No. 2 YiKuang Street, Science Park of Harbin Institute of Technology (HIT), Harbin 150080, P.R.
All the materials’ recovery rates were above 97% at Tg.
Progress in Materials Science, 98, 174105
Shape-Memory Polymers-A Class of Novel Smart Materials.
‘‘Electroactive Thermoset Shape Memory Polymer Nanocomposite Filled with Nanocarbon Powders,’’ Smart Materials & Structures, 18:074003
All the materials’ recovery rates were above 97% at Tg.
Progress in Materials Science, 98, 174105
Shape-Memory Polymers-A Class of Novel Smart Materials.
‘‘Electroactive Thermoset Shape Memory Polymer Nanocomposite Filled with Nanocarbon Powders,’’ Smart Materials & Structures, 18:074003
Online since: September 2013
Authors: Hong Ying Gong, Hui Xiao Li, Xiao Bin Su, Si Fan Wang, Yun Long Fu
Studies on the tensile properties and flow performance of the different molecular-weight polycarbonate
Hong-ying Gonga, yun-long,Fub, X.B.Su, H.X.Li, S.F.Wang
College of Materials Engineering, Shanghai University of Engineering Science, Shanghai 201620,china
aemail:ghyyw@163.com,bemail:fuyunlong0715@126.com
Keywords: polycarbonate; molecular-weight; tensile properties; SEM; flow performance
Abstract.
True stress-strain curves are shown in figure 4 what reflected the mechanical characteristics of rod materials in plastic deformation stage.
[5] Qinzhi Fang,T.J.Wang,H.M.Li: International Journal of Fatigue.Vol.30(2008),p.1419
[10] G.Kermouche,J.L.Loubet,J.M.Bergheau: Mechanics of Materials.Vol.40(2008).p,271
[15] Jan Musil,Martin Zatloukal: Chemical Engineering Science.Vol.66(2011).p,4814
True stress-strain curves are shown in figure 4 what reflected the mechanical characteristics of rod materials in plastic deformation stage.
[5] Qinzhi Fang,T.J.Wang,H.M.Li: International Journal of Fatigue.Vol.30(2008),p.1419
[10] G.Kermouche,J.L.Loubet,J.M.Bergheau: Mechanics of Materials.Vol.40(2008).p,271
[15] Jan Musil,Martin Zatloukal: Chemical Engineering Science.Vol.66(2011).p,4814
Online since: October 2007
Authors: Yu Chan Kim, Eric Fleury, Young-Kook Lee, Oh Jib Kwon, Jin Ju Lee
Gook: Materials Transactions JIM Vol. 36 (1995), p. 1180
Inoue: Journal of Materials Research Vol. 20 (2005), p. 1
Johnson: Progress in Materials Science Vol. 30 (1986), p. 81
Lim: Science and Technology of Advanced Materials Vol. 6 (2005), p. 256
Fleury: Materials Science and Engineering A Vol. 449-451 (2007), p. 169
Inoue: Journal of Materials Research Vol. 20 (2005), p. 1
Johnson: Progress in Materials Science Vol. 30 (1986), p. 81
Lim: Science and Technology of Advanced Materials Vol. 6 (2005), p. 256
Fleury: Materials Science and Engineering A Vol. 449-451 (2007), p. 169
Online since: October 2014
Authors: Sorin Vasile Savu
Fig. 4 Comparative heating curves for sample and inert materials
a.
Inert Material In figure 4.a is presented a comparative study of the sample materials to identify their behaviour at the microwave heating.
The similar behaviour can be explained by the fact that all three inert materials are already sintered materials and chemical and physic reaction will not be present.
That is possible because the materials strongly polarized by the electromagnetic field applied.
Metaxas – Microwave Heating – IEE Power Engineering Journal 5(5) 1991, http://www.pueschner.com/downloads [5] Ciupitu, I., et al. - The improving of the process of the iron, the cast iron and the copper powder mixing, Materials Science Forum Vol. 672 (2011), pag. 76-79, edited by Trans.
Inert Material In figure 4.a is presented a comparative study of the sample materials to identify their behaviour at the microwave heating.
The similar behaviour can be explained by the fact that all three inert materials are already sintered materials and chemical and physic reaction will not be present.
That is possible because the materials strongly polarized by the electromagnetic field applied.
Metaxas – Microwave Heating – IEE Power Engineering Journal 5(5) 1991, http://www.pueschner.com/downloads [5] Ciupitu, I., et al. - The improving of the process of the iron, the cast iron and the copper powder mixing, Materials Science Forum Vol. 672 (2011), pag. 76-79, edited by Trans.