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Online since: May 2015
Authors: Shun Fa Hwang, Yuder Chen, Yi Lung Lin
Introduction
Composite materials have the characteristics of high modulus/weight and strength/weight ratios, excellent fatigue properties, and noncorroding behavior.
These advantages encourage the extensive application of composite materials, for example, in sports and aerospace.
In addition, the complex mechanical behavior of composite materials makes their design problem more difficulty.
Mishing, in: Diffusion Processes in Advanced Technological Materials, edtied by D.
Clem: submitted to Journal of Materials Research (2003) [36] I.K.
These advantages encourage the extensive application of composite materials, for example, in sports and aerospace.
In addition, the complex mechanical behavior of composite materials makes their design problem more difficulty.
Mishing, in: Diffusion Processes in Advanced Technological Materials, edtied by D.
Clem: submitted to Journal of Materials Research (2003) [36] I.K.
Online since: August 2021
Authors: Volodymyr V. Drahobetskyi, Mykhailo E. Taranenko, Viktoriia D. Kulynych
The shell materials were varied: aviation aluminum and titanium alloys, high-strength steels and heat-resistant alloys (Fig. 1).
Yudenkov, Time relaxation of point defects in p- and n-(HgCd)Te after ion milling, Journal of Electronic Materials. 32(7) (2003) 698-702
Balalayeva, Effect of particular combinations of quenching, tempering and carburization on abrasive wear of low-carbon manganese steels with metastable austenite, Materials Science Forum. 945 (2019) 574-578
Key Engineering Materials, 864 (2020) 285-291
Gurenko, Modeling dynamic parameters of hard alloys during shock wave regeneration, IOP Conference Series: Materials Science and Engineering. 969(1) (2020) № 012079
Yudenkov, Time relaxation of point defects in p- and n-(HgCd)Te after ion milling, Journal of Electronic Materials. 32(7) (2003) 698-702
Balalayeva, Effect of particular combinations of quenching, tempering and carburization on abrasive wear of low-carbon manganese steels with metastable austenite, Materials Science Forum. 945 (2019) 574-578
Key Engineering Materials, 864 (2020) 285-291
Gurenko, Modeling dynamic parameters of hard alloys during shock wave regeneration, IOP Conference Series: Materials Science and Engineering. 969(1) (2020) № 012079
Online since: September 2018
Authors: Juliana Simões Chagas Licurgo, Herval Ramos Paes Junior
Ciofini: Advanced Functional Materials Vol. 21 (2011), p. 3564
Oral: Optical Materials Vol. 29 (2007), p. 672
Gwag: Materials Science in Semiconductor Processing Vol. 49 (2016), p. 8
Bu: Materials Science in Semiconductor Processing Vol. 41 (2016), p. 240
Kawamura: Materials Letters Vol. 149 (2015), p. 8
Oral: Optical Materials Vol. 29 (2007), p. 672
Gwag: Materials Science in Semiconductor Processing Vol. 49 (2016), p. 8
Bu: Materials Science in Semiconductor Processing Vol. 41 (2016), p. 240
Kawamura: Materials Letters Vol. 149 (2015), p. 8
Online since: January 2017
Authors: Jia Yue Sun, Deng Hui Xu, Yao Hui Zhu, Zai Fa Yang, Xue Dong Gao, Jiang Nan Du
Materials Letters, 2007, 61(17): 3696-3700
Materials Research Bulletin, 2016, 75: 211-216
Applied Mechanics & Materials, 2014, 597:109-112
Materials Research Bulletin, 1978, 13(9): 953-957
Journal of Materials Chemistry, 2011, 21(5): 1387-1394
Materials Research Bulletin, 2016, 75: 211-216
Applied Mechanics & Materials, 2014, 597:109-112
Materials Research Bulletin, 1978, 13(9): 953-957
Journal of Materials Chemistry, 2011, 21(5): 1387-1394
Online since: September 2014
Authors: Zainal Arifin Ahmad, Saidatulakmar Shamsuddin, Wan Nurul Syaza Wan Nawai, Norhanida Awang Kasani, Razif Nordin
Introduction
Ti-6Al-4V ELI was the first generation of titanium alloy used as biomedical materials and it is widely used.
The structure and mechanical properties of as-cast Ti-25Nb-xSn alloys for biomedical applications, Materials Science & Engineering A, 568 (2013) 1-7
Advances Materials Research., 620 (2013) 362-367
J Materials and Design, 49 (2013) 511-519
Effect of porosity and density on the mechanical and microstructural properties of sintered 316L stainless steel implant materials, Materials and Design, 55 (2014) 235-241
The structure and mechanical properties of as-cast Ti-25Nb-xSn alloys for biomedical applications, Materials Science & Engineering A, 568 (2013) 1-7
Advances Materials Research., 620 (2013) 362-367
J Materials and Design, 49 (2013) 511-519
Effect of porosity and density on the mechanical and microstructural properties of sintered 316L stainless steel implant materials, Materials and Design, 55 (2014) 235-241
Online since: July 2007
Authors: Xiao Ying Lü, Qing Yue Hong, Pai Zheng Sun, Jian He, Yan Huang, Zu Hong Lu
Introduction:
The interactions between biomaterials and human body will happen on their interface
immediately after materials are inserted into human body.
Material and Methods: Materials: Human Alb, Fib and IgG(Sigma) solutions were freshly prepared in 10 mM phosphate buffered saline (PBS, pH 7.4) to a concentration of 1mg/ml before each experiment.
It is reported that fibrinogen and IgG promotes platelet adhesion on a materials surface, and then leads to blood coagulation and form thrombus at last, whereas albumin has thromboresistant ability.
Roos, et al: Journal of Colloid and Interface Science, 1991, 143(2):p.513 [3] R.J.
Gong, et al: Chinese Journal of Biomedical Engineering, 2000, 19(1):p.60 [7] X.Y.
Material and Methods: Materials: Human Alb, Fib and IgG(Sigma) solutions were freshly prepared in 10 mM phosphate buffered saline (PBS, pH 7.4) to a concentration of 1mg/ml before each experiment.
It is reported that fibrinogen and IgG promotes platelet adhesion on a materials surface, and then leads to blood coagulation and form thrombus at last, whereas albumin has thromboresistant ability.
Roos, et al: Journal of Colloid and Interface Science, 1991, 143(2):p.513 [3] R.J.
Gong, et al: Chinese Journal of Biomedical Engineering, 2000, 19(1):p.60 [7] X.Y.
Online since: January 2014
Authors: Qing Kun He, Chang Ying Shi
Application of Electron Probe Microanalyzer (EPMA) to Depositional Environment Identification of Sedimentary Rock
Qingkun He1, a, Changying Shi2, b
1College of Materials science and engineering, Shandong university of science and technology, Qingdao 266590, China
2Key Laboratory of Depositional Mineralization & Sedimentary Mineral (SDUST), Shandong Province, Qingdao, Shandong 266510, China)
aqingkunhe@163.com, bdizhishichangying@163.com
Keywords: EPMA , depositional, identification, sedimentary rock
Abstracts: Electron microprobe technology is widely used to component analysis of metals, minerals and geology.
Introduction Electron probe microanalyzer(EPMA), a common instrument to study the elements of material surface, can scan anywhere of material surface and analyze the material elements easily by the analysis of X-ray which can be induced when the electron beam hit the surface of materials.
Popular science press, 1984
Journal of China University of Mining [10] Rennong Wang.
Chinese Journal of Geology, 1977, 4 [11] Yangyong, Nengsong Chen.
Introduction Electron probe microanalyzer(EPMA), a common instrument to study the elements of material surface, can scan anywhere of material surface and analyze the material elements easily by the analysis of X-ray which can be induced when the electron beam hit the surface of materials.
Popular science press, 1984
Journal of China University of Mining [10] Rennong Wang.
Chinese Journal of Geology, 1977, 4 [11] Yangyong, Nengsong Chen.
Online since: June 2015
Authors: H.J.M. Ridzwan, N.H. Jamil, S.A. Syamsyir, W.A.W. Razali
Syamsyir2,c, W.A.W.Razali2,d.
1Faculty of Applied Sciences (Chemistry), Universiti Teknologi MARA Pahang, Lintasan Semarak, Bandar Jengka, Pahang, 26400 Malaysia
2Faculty of Applied Sciences (Physics), Universiti Teknologi MARA Pahang, Lintasan Semarak, Bandar Jengka, Pahang, 26400 Malaysia
ahendrie@pahang.uitm.my, bmynameiskc_89@yahoo.com, csyamsyir@pahang.uitm.my, dwanaizuddin@pahang.uitm.edu.my
Keywords: Bioactive glass, Strontium oxide, Simulated body fluid, Hydroxyapatite.
Introduction Inorganic bioactive materials of silicate glass have been studied for more than forty years since Hench and his co-workers invented Bioglass® [1].
Greenle, Bonding mechanisms at the interface of ceramic prosthetic materials, Journal of Biomedical Materials Research. 5(6) (1971) 117-141
Stevens, Materials characterisation and cytotoxic assessment of strontium-substituted bioactive glasses for bone regeneration, Journal of Materials Chemistry. 20(40) (2010) 8934–41
Hench, Bioceramics –from concept to clinic, Journal of the American Ceramic Society. 74 (1991) 1487-1510.
Introduction Inorganic bioactive materials of silicate glass have been studied for more than forty years since Hench and his co-workers invented Bioglass® [1].
Greenle, Bonding mechanisms at the interface of ceramic prosthetic materials, Journal of Biomedical Materials Research. 5(6) (1971) 117-141
Stevens, Materials characterisation and cytotoxic assessment of strontium-substituted bioactive glasses for bone regeneration, Journal of Materials Chemistry. 20(40) (2010) 8934–41
Hench, Bioceramics –from concept to clinic, Journal of the American Ceramic Society. 74 (1991) 1487-1510.
Online since: October 2010
Authors: Ming Fu Wang, Yong Tang Li, Xu Dong Li, Zhi Qi Liu, Jian Li Song
Process and Properties on the Precision Forming of Spline Cold Rolling
Zhiqi Liu1,2, a, Jianli song2,b, Yongtang Li2,c, Xudong Li 1,d Mingfu Wang2,e ,
1 State Key Laboratory of Gansu Advanced Non-Ferrous Metal Materials, Lanzhou University of Science & Technology, Lanzhou 730050 ,China;
2 School of Materials Science and Engineering, Taiyuan University of Science & Technology, Taiyuan 030024,China
alzq_678@yahoo.com.cn, bsongjianli06@sina.com, cliyongtang@tyust.edu.cn, dlixd@lut.cn,ewmf354@163.com,
Keywords: cold rolling forming, plastic flow of metals, distribution of hardness
Abstract.
Materials flow analysis of the tooth outline Parts of the formed spline components are shown in Fig.3(a).
Deformation flow seldom occurred on the materials below the root of the tooth.
The materials flow along the side flank of the tooth round the bottom of the tooth angle.
Domblesky, Feng Feng: Wire Journal International, Vol .34 (2001),p110 [5] Wu Xiuyi: Machinery Manufacturing Engineer. 1997,000 (001),p 15, in Chinese [6] Zheng Quangang: Automobile Technology & Material. 1997,000 (007),p16, in Chinese [7] Li Yongtang, Song Jianli, Zhang Dawei, et al:Materials Science Forum, 2007, 575-578,p416 [8] LIU Zhi-qi, LI Xu-dong, LI Yong-tang: Journal Of Lanzhou University Of Technology.
Materials flow analysis of the tooth outline Parts of the formed spline components are shown in Fig.3(a).
Deformation flow seldom occurred on the materials below the root of the tooth.
The materials flow along the side flank of the tooth round the bottom of the tooth angle.
Domblesky, Feng Feng: Wire Journal International, Vol .34 (2001),p110 [5] Wu Xiuyi: Machinery Manufacturing Engineer. 1997,000 (001),p 15, in Chinese [6] Zheng Quangang: Automobile Technology & Material. 1997,000 (007),p16, in Chinese [7] Li Yongtang, Song Jianli, Zhang Dawei, et al:Materials Science Forum, 2007, 575-578,p416 [8] LIU Zhi-qi, LI Xu-dong, LI Yong-tang: Journal Of Lanzhou University Of Technology.
Online since: April 2004
Authors: Sung Mo Yang, Hong Gil Noh, Dong Joo Lee, Hong Gun Kim
materials.
INTRODUCTION Composite is one of the strongest candidates as a structural material for many aerospace and other applications[1,2].
J., "Elastic-Plastic Element Analysis of Short Fiber Composites," Fiber Science and Technology, Vol. 7, pp. 45-62, 1974 3.
L., "The Elasticity and Strength of Paper and Other Fibrous Materials," British Jounal of Applied Physics, Vol. 3, pp. 72-79, 1952 4.
G, "Analytical Study on the Elastic-Plastic Transition in Short Fiber Reinforced Composites",KSME International Journal, Vol. 12, No. 2, pp. 257-266, 1998 9.
INTRODUCTION Composite is one of the strongest candidates as a structural material for many aerospace and other applications[1,2].
J., "Elastic-Plastic Element Analysis of Short Fiber Composites," Fiber Science and Technology, Vol. 7, pp. 45-62, 1974 3.
L., "The Elasticity and Strength of Paper and Other Fibrous Materials," British Jounal of Applied Physics, Vol. 3, pp. 72-79, 1952 4.
G, "Analytical Study on the Elastic-Plastic Transition in Short Fiber Reinforced Composites",KSME International Journal, Vol. 12, No. 2, pp. 257-266, 1998 9.