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Online since: March 2012
Authors: Chun Ming Liu, Zhan Yong Zhao, Run Ze Chao, Ren Guo Guan, Chao Lian
Bevis: Materials Science and Engineering Vol. 299 (2001), p. 210
[8] S.P.
Watari: Journal of Materials Processing Technology, Vol. 42 (2004), p. 153 [11] P.
Liu, J.Z Cui: Materials Science and Technology Vol. 17 (2009), p. 43 [12] T.
Wang: Materials Science Forum Vol. 561-565 (2007), p. 865 [14] R.G.
Wang: Journal of Materials Processing Technology Vol. 209 (2009), p.2592 [15] R.B.
Watari: Journal of Materials Processing Technology, Vol. 42 (2004), p. 153 [11] P.
Liu, J.Z Cui: Materials Science and Technology Vol. 17 (2009), p. 43 [12] T.
Wang: Materials Science Forum Vol. 561-565 (2007), p. 865 [14] R.G.
Wang: Journal of Materials Processing Technology Vol. 209 (2009), p.2592 [15] R.B.
Online since: March 2015
Authors: Yue Gu, Ying Liu, Shu Lai Wen, Hong Li, Yuan Wang, Xiu Chen Zhao
[2] Ma H, Suhling JC : Journal of Materials Science. 44(2009) 1141-1158
[3] El-Daly AA, Fawzy A, Mansour SF and Younis MJ: Journal of Materials Science: Materials in Electronics. 24(2013) 2976-2988
[11] Ma L, Tai F, Xu G, Guo F, Wang X: Journal of Electronic Materials. 40(2011 1416-1421
[12] Pan H-C, Hsieh T-E: Journal of Electronic Materials. 40(2011) 330-339
[16] Ma L, Xu G, Sun J, Guo F, Wang X: Journal of Materials Science. 46(2011) 4896-4905
[3] El-Daly AA, Fawzy A, Mansour SF and Younis MJ: Journal of Materials Science: Materials in Electronics. 24(2013) 2976-2988
[11] Ma L, Tai F, Xu G, Guo F, Wang X: Journal of Electronic Materials. 40(2011 1416-1421
[12] Pan H-C, Hsieh T-E: Journal of Electronic Materials. 40(2011) 330-339
[16] Ma L, Xu G, Sun J, Guo F, Wang X: Journal of Materials Science. 46(2011) 4896-4905
Online since: June 2013
Authors: Elder Cunha de Lira, Kelly Cristiane Gomes, Andre R.R. de Sousa, Marçal Rosas, Sandro Marden Torrres, Silvio Romero de Barros
Mackenzie: Materials Research Bulletin Vol 38 (2002), pp. 319-331
Escott and D.J Cassidy: Journal of Material Science Vol. 41 (2006), pp. 1261-1264
Davidovits: Journal of Thermal Analysis, Vol. 37 (1991), pp. 1633
Torres: Materials Science Forum Vol. 643 (2010); pp. 143-146
Barbosa: Materials Science Forum Vol. 643 (2010), pp. 131-138.
Escott and D.J Cassidy: Journal of Material Science Vol. 41 (2006), pp. 1261-1264
Davidovits: Journal of Thermal Analysis, Vol. 37 (1991), pp. 1633
Torres: Materials Science Forum Vol. 643 (2010); pp. 143-146
Barbosa: Materials Science Forum Vol. 643 (2010), pp. 131-138.
Online since: March 2007
Authors: G. Matula, José Manuel Torralba, Leszek Adam Dobrzański, A. Kloc
Torralba
2
1, Division of Materials Processing Technology and Computer Techniques in Materials Science,
Institute of Engineering Materials and Biomaterials, Silesian University of Technology,
Konarskiego St. 18a, 44-100 Gliwice, Poland
2, Universidad Carlos III de Madrid, Avda.
Functionally gradient materials (FGM) are materials whose properties change in their volume.
Higher high-speed steel density in pressurelessly formed materials, in comparison with the high-speed steel density in compacted and sintered materials, is caused by higher carbon concentration.
Hence the sintering temperature corresponding to the maximum density of the pressurelessly formed materials is lower in comparison with the materials made using traditional powder metallurgy methods.
Matula, Struktura i własności spiekanej stali szybkotnącej HS6-5-2 formowanej wtryskowo, Proceedings of the third scientific conference M3E'2005, Gliwice - Wisła [7] Miyamoto Z., Kaysser W.M., Rabin B.H., Kawasaki A., Ford R.G., Functionally Graded Materials, Kluwer Academic Publisher, Boston, 1999 [8] Kieback B., Neubrand A., Riedel H., Processing techniques for functionally graded materials, Materials Science and Engineering: A Volume:362, Issue: 1-2, Grudzień 5, 2003, p.81-106 [9] Lengauer W., Dreyer K., Functionally graded hardmetals, Journal of Alloys and Compounds, 338, 2002, p. 194-212 [10] Bever M.B., Duwez P.F., Mater.
Functionally gradient materials (FGM) are materials whose properties change in their volume.
Higher high-speed steel density in pressurelessly formed materials, in comparison with the high-speed steel density in compacted and sintered materials, is caused by higher carbon concentration.
Hence the sintering temperature corresponding to the maximum density of the pressurelessly formed materials is lower in comparison with the materials made using traditional powder metallurgy methods.
Matula, Struktura i własności spiekanej stali szybkotnącej HS6-5-2 formowanej wtryskowo, Proceedings of the third scientific conference M3E'2005, Gliwice - Wisła [7] Miyamoto Z., Kaysser W.M., Rabin B.H., Kawasaki A., Ford R.G., Functionally Graded Materials, Kluwer Academic Publisher, Boston, 1999 [8] Kieback B., Neubrand A., Riedel H., Processing techniques for functionally graded materials, Materials Science and Engineering: A Volume:362, Issue: 1-2, Grudzień 5, 2003, p.81-106 [9] Lengauer W., Dreyer K., Functionally graded hardmetals, Journal of Alloys and Compounds, 338, 2002, p. 194-212 [10] Bever M.B., Duwez P.F., Mater.
Online since: April 2014
Authors: F. Pınar Gokdemir, Ece Yuzbasioglu, A. Evrim Saatci, Orhan Ozdemir, Kubilay Kutlu
Murafa, Materials Chemistry and Physics 114 (2009), p.217
Kanno, Journal of Material Processing Technology 209 (2009), p.2321
Padmanabhan, Materials Science and Engineering B 143 (2007), p.42
Ma, Materials Letters Vol. 62 12–13 (2008), p.1835
Granqvist, “Handbook of Inorganic Electrochromic Materials” (Elsevier, The Netherlands, 1995)
Kanno, Journal of Material Processing Technology 209 (2009), p.2321
Padmanabhan, Materials Science and Engineering B 143 (2007), p.42
Ma, Materials Letters Vol. 62 12–13 (2008), p.1835
Granqvist, “Handbook of Inorganic Electrochromic Materials” (Elsevier, The Netherlands, 1995)
Online since: February 2011
Authors: Yin Fang Jiang, Lei Fang, Zhi Fei Li, Zhen Zhou Tang
Laser shock processing is a technique similar to shot peening that imparts compressive residual stresses in materials for improved fatigue resistance.
LSP is a process similar to traditional shot peening and designed to improve the mechanical properties and fatigue performance of materials [1].
Acknowledgements This research is financed by Natural Science Fund (51075193) References [1] William.Braisted and Robert.
Brockman: International Journal of Fatigue Vol.21 (1999), P.719–724
Yang: Chinese Journal of Lasers Vol. 33 (2006), pp. 1282-1287
LSP is a process similar to traditional shot peening and designed to improve the mechanical properties and fatigue performance of materials [1].
Acknowledgements This research is financed by Natural Science Fund (51075193) References [1] William.Braisted and Robert.
Brockman: International Journal of Fatigue Vol.21 (1999), P.719–724
Yang: Chinese Journal of Lasers Vol. 33 (2006), pp. 1282-1287
Online since: February 2018
Authors: Jong Hoon Yoon, Ho Sung Lee, Joon Tae Yoo, Koo Kil No
The materials were switched to study the effect of welding direction.
Wilson, Welding Journal, 63(1984) pp. 27-35
Ma, Materials Science and Engineering R 50 (2005) pp.1–78
Lee, Korean Journal of Materials Research 27 (2017) pp.331-338
Muhammed, Asian Research Publishing Network Journal of Engineering and Applied Sciences, 7(2012) pp.436-446
Wilson, Welding Journal, 63(1984) pp. 27-35
Ma, Materials Science and Engineering R 50 (2005) pp.1–78
Lee, Korean Journal of Materials Research 27 (2017) pp.331-338
Muhammed, Asian Research Publishing Network Journal of Engineering and Applied Sciences, 7(2012) pp.436-446
Online since: May 2015
Authors: Yuan Yuan Liu, Qing Xi Hu, Ya Nan Zhang, Yu Li, Shuai Li
Materials.
Advanced Materials. 26 (2014) 4961-4966
Journal of Polymer Science Part A: Polymer Chemistry. 42( 2004) 624-638
Materials Today. 16 (2013) 496-504
Journal of Biomedical Materials Research Part A. 101A (2013) 1103-1112
Advanced Materials. 26 (2014) 4961-4966
Journal of Polymer Science Part A: Polymer Chemistry. 42( 2004) 624-638
Materials Today. 16 (2013) 496-504
Journal of Biomedical Materials Research Part A. 101A (2013) 1103-1112
Online since: December 2012
Authors: Fang Ma, Li Wang, Xiao Xian Zhang
Journal of Anhui Agricultural Sciences. 5(2010) . p. 2553
[10] A.
Journal of Agro-Environment Science. 7(2010) . p. 1417 [19] Z.
Journal of Agro-Environment Science. 2(2009) . p. 420 [29] M.
Journal of Agro-Environment Science. 10(2009) . p. 2204 [32] M.
Journal of Agro-Environment Science. 5(2006) . p. 1127
Journal of Agro-Environment Science. 7(2010) . p. 1417 [19] Z.
Journal of Agro-Environment Science. 2(2009) . p. 420 [29] M.
Journal of Agro-Environment Science. 10(2009) . p. 2204 [32] M.
Journal of Agro-Environment Science. 5(2006) . p. 1127
Online since: April 2019
Authors: Atike Ince Yardimci, Hande Aypek, Ozgur Ozturk, Selahattin Yilmaz, Engin Ozcivici, Gulistan Mese, Yusuf Selamet
Materials and Methods
2.1.
Ko, Electrospun nanofibrous structure: a novel scaffold for tissue engineering, Journal of biomedical materials research, 60 (2002) 613-621
Ramakrishna, Polypyrrole‐contained electrospun conductive nanofibrous membranes for cardiac tissue engineering, Journal of biomedical materials research Part A, 99 (2011) 376-385
Kaneto, TFSI-doped polypyrrole actuator with 26% strain, Journal of Materials Chemistry, 14 (2004) 1516-1517
Popov, Carbon nanotubes: properties and application, Materials Science and Engineering: R: Reports, 43 (2004) 61-102
Ko, Electrospun nanofibrous structure: a novel scaffold for tissue engineering, Journal of biomedical materials research, 60 (2002) 613-621
Ramakrishna, Polypyrrole‐contained electrospun conductive nanofibrous membranes for cardiac tissue engineering, Journal of biomedical materials research Part A, 99 (2011) 376-385
Kaneto, TFSI-doped polypyrrole actuator with 26% strain, Journal of Materials Chemistry, 14 (2004) 1516-1517
Popov, Carbon nanotubes: properties and application, Materials Science and Engineering: R: Reports, 43 (2004) 61-102