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Online since: July 2014
Authors: Vijayan Krishnaraj, Arasu P. Manuneethi, B. Rambabu
New cars - new materials (1997).
Materials & Design: Vol. 18:203–209
Journal of Materials Processing Technology: Vol. 115: 2–8
Journal of Materials Processing Technology; Vol. 175: 398–403
Eco-composite: the effects of the jute fiber treatments on the mechanical and environmental performance of the composite materials Journal of Composite Materials (2011); Vol. 45: 573-589
Materials & Design: Vol. 18:203–209
Journal of Materials Processing Technology: Vol. 115: 2–8
Journal of Materials Processing Technology; Vol. 175: 398–403
Eco-composite: the effects of the jute fiber treatments on the mechanical and environmental performance of the composite materials Journal of Composite Materials (2011); Vol. 45: 573-589
Online since: August 2012
Authors: Jian Xin Zhang, Guo Hua Zhang, Bing Chao Li, Wei Cai, Zuo Shan Wei, Zeng Jian Feng
Effect of intermetallics on the low cyclic fatigue crack growth behavior of a heavily alloyed Al-Si piston alloy
Guo-hua ZHANG1,3, Bing-chao LI2, Jian-xin ZHANG2, Zeng-jian FENG3, Zuo-shan WEI3, Wei CAI1*
1School of Materials Science and Engineering, Harbin Institute of Technology, Harbin 150001, China
2 School of Materials Science and Engineering, Shandong University, Jinan 250061, China
3 Shandong Binzhou Bohai Piston Co., Ltd, Binzhou 256602, China
Guo-hua ZHANG1,3: zhangmater@yahoo.com; Jian-xin ZHANG2: jianxin@sdu.edu.cn;
Wei CAI1: alsialloy@yahoo.com; *corresponding author
Keywords: aluminum alloys; low cyclic fatigue; crack growth; fracture; intermetallics
Abstract
This paper focuses on a typical automotive piston material to characterize its fractographic appearance after low cyclic fatigue test.
Materials Science and Engineering A, 2000, 280: 8-16
Arzt, High temperature, low cycle fatigue behaviour of an aluminium alloy (Al–12Si–CuMgNi), Materials Science and Engineering A276 (2000) 283–287 [6] Ma Z.
Materials and Design, 2002, 23: 141-151
International Journal of Fatigue, 2005, 27: 1564-1570
Materials Science and Engineering A, 2000, 280: 8-16
Arzt, High temperature, low cycle fatigue behaviour of an aluminium alloy (Al–12Si–CuMgNi), Materials Science and Engineering A276 (2000) 283–287 [6] Ma Z.
Materials and Design, 2002, 23: 141-151
International Journal of Fatigue, 2005, 27: 1564-1570
Online since: August 2013
Authors: Alexey Sobachkin, A.V. Sobachkin, A.A. Sitnikov
Application of self-propagating high-temperature synthesis and mechanoactivating treatment for producing multi-component composite alloying materials
V.
The fundamental research laboratory of SHS materials science of Altai STU suggests using the powders of materials produced by mechanically activated SHS as electrode mix material components.
Chakhlykh // Self-propagating high-temperature synthesis: materials and technologies.
[6] Manual arc coating for the work tools of agricultural machines produced from mechanically activated SHS-materials / A.A.
Tatarkin // Polzunov Journal. 2012. № 1/1.
The fundamental research laboratory of SHS materials science of Altai STU suggests using the powders of materials produced by mechanically activated SHS as electrode mix material components.
Chakhlykh // Self-propagating high-temperature synthesis: materials and technologies.
[6] Manual arc coating for the work tools of agricultural machines produced from mechanically activated SHS-materials / A.A.
Tatarkin // Polzunov Journal. 2012. № 1/1.
Online since: March 2017
Authors: Razali Mohd Hasmizam, Khairul Anuar, Nur Arifah Ismail, Mat Amin
Characterization of Nanostructured Titania and Titanate Materials Synthesized by Simple Hydrothermal Method
Nur Arifah Ismaila, Mohd Hasmizam Razalib, Khairul Anuar and Mat Aminc
School of Fundamental Sciences, Universiti Malaysia Terengganu,
21030 Kuala Terengganu, Terengganu Darul Iman, Malaysia.
Materials Science in Semiconductor Processing Vol. 42 (2016), p. 131
Materials Research Bulletin, Vol. 74 (2016), p. 478
Solar Energy Materials and Solar Cells, Vol. 151, (2016), p. 169
Materials Chemistry and Physics Vol. 78 (2003), p. 239
Materials Science in Semiconductor Processing Vol. 42 (2016), p. 131
Materials Research Bulletin, Vol. 74 (2016), p. 478
Solar Energy Materials and Solar Cells, Vol. 151, (2016), p. 169
Materials Chemistry and Physics Vol. 78 (2003), p. 239
Online since: November 2013
Authors: Yi Bo Wang, Yong Hong Liu, Wei Fu, Li Cheng Chen, Yao Zhong Li, Su Hua Wu
Materials and methods
Home-made MEM and MER.
The main components of iron mud are all that of homemade MEM, so iron mud can be recycled as raw materials for the synthesis of MEM.
Journal of Hazardous Material, vol. 169(2009), p.480
Journal of Hazardous Materials, vol. 164(2009), p. 1392
Journal of Environmental Sciences, vol. 15(2003), p. 334
The main components of iron mud are all that of homemade MEM, so iron mud can be recycled as raw materials for the synthesis of MEM.
Journal of Hazardous Material, vol. 169(2009), p.480
Journal of Hazardous Materials, vol. 164(2009), p. 1392
Journal of Environmental Sciences, vol. 15(2003), p. 334
Online since: December 2006
Authors: Yong Kang Zhang, Ai Xin Feng, Ling Feng Zhang
SEM was conducted in an ASM-SX microscope in school of material science and engineering of
Jiangsu University.
Balke and et al: Materials Science and Engineering, Vol.A362 (2003), pp.2-16
Li, and et a: Chinese Journal of Materials Research,Vol.15 (2001), pp.693-697
Morelli: Journal of Materials Processing Technology, Vol.143 (2003), pp.232-236
Jin: Chinese Journal of Materials Research, Vol.10 (1996), pp.45-48.
Balke and et al: Materials Science and Engineering, Vol.A362 (2003), pp.2-16
Li, and et a: Chinese Journal of Materials Research,Vol.15 (2001), pp.693-697
Morelli: Journal of Materials Processing Technology, Vol.143 (2003), pp.232-236
Jin: Chinese Journal of Materials Research, Vol.10 (1996), pp.45-48.
Online since: January 2016
Authors: A.M. Mustafa Al Bakri, Mohammed Binhussain, Hussin Kamarudin, Shamala Ramasamy, Che Mohd Ruzaidi Ghazali, Noor Fifinatasha Shahedan, Andrei Victor Sandu
Introduction
Geopolymeric materials are materials rich with Al and Si that are now widely being investigated as promising green material [1-3].
Rafiza, and Y.Zarina //Advanced Materials Research 328,(2011) 1475-1482
Rafiza //Advanced Materials Research 341,(2011)189-193
Izzat //International Journal of Molecular Science 13,(2012) 4388-4395
Rafiza //International Journal of Molecular Science 13,(2012) 7186-7196
Rafiza, and Y.Zarina //Advanced Materials Research 328,(2011) 1475-1482
Rafiza //Advanced Materials Research 341,(2011)189-193
Izzat //International Journal of Molecular Science 13,(2012) 4388-4395
Rafiza //International Journal of Molecular Science 13,(2012) 7186-7196
Online since: May 2013
Authors: Jin Shui Wang, Feng Jia, Guo Hao Yang, Bin Jian Qi, Jun Jun Guan, Bing Qian Han
Materials and Methods
Materials.
[2] Zhang M, Huang G, Jiang J: Advance Journal of Food Science and Technology Vol. 4 (2012), p.78-83
[8] Song Q, Huang Y, Yang H: Journal of Agricultural Science Vol. 4 (2012), p.95-102
[9] YANG Y,QIAO L: Journal of Beijing University of Agriculture Vol. 25 (2010), p.18-20
[11] Chen T, Wei Q, Chi Z: African Journal of Microbiology Research Vol. 5 (2011), p.2011-2018
[2] Zhang M, Huang G, Jiang J: Advance Journal of Food Science and Technology Vol. 4 (2012), p.78-83
[8] Song Q, Huang Y, Yang H: Journal of Agricultural Science Vol. 4 (2012), p.95-102
[9] YANG Y,QIAO L: Journal of Beijing University of Agriculture Vol. 25 (2010), p.18-20
[11] Chen T, Wei Q, Chi Z: African Journal of Microbiology Research Vol. 5 (2011), p.2011-2018
Online since: October 2013
Authors: Yun Fei Zhang
Conclusion
The development of low-carbon construction is a systematic project , low-carbon building materials and energy-saving equipment are its material and technical support , and the essential meaning of the quality of the various stages involved in the life cycle carbon emissions .From an overall point of view, the entire life cycle of low-carbon building development is the successful development of low-carbon buildings.
National Cheng Kung University Institute of Architecture , 2007 [7] Leng Faguang, Zhang Renytu , Xing Feng.The development and application of the green building materials and green high-performance concrete .
The trend of the development of new energy-saving building materials.
Journal of Hei longjiang science and technology information, 2008 (36):34-37 [9] Mao Zhibing,Yu Zhenping.
Journal of construction technology, 2012 (12):49-52.
National Cheng Kung University Institute of Architecture , 2007 [7] Leng Faguang, Zhang Renytu , Xing Feng.The development and application of the green building materials and green high-performance concrete .
The trend of the development of new energy-saving building materials.
Journal of Hei longjiang science and technology information, 2008 (36):34-37 [9] Mao Zhibing,Yu Zhenping.
Journal of construction technology, 2012 (12):49-52.
Online since: October 2014
Authors: Hong Zhong Cai, Xiao Hong Qi, Chang Yi Hu, Yan Wei, Li Chen, Xu Zheng
Journal of Nuclear materials, 2005, 340(1): 93-112
Journal of Materials Science & Technology, 2003, 19(3):213-217 [5] Hou P Y, Tolpygo V K.
International Journal of Refractory Metals and Hard Materials, 2008, 26(6): 549-554
International Journal of Refractory metals and hard materials, 1994, 12(5): 283-293
Materials Science and Engineering A 486 (2008) 556–561 [19] Zheng X H, Du Y G, Xiao J Y, et al.
Journal of Materials Science & Technology, 2003, 19(3):213-217 [5] Hou P Y, Tolpygo V K.
International Journal of Refractory Metals and Hard Materials, 2008, 26(6): 549-554
International Journal of Refractory metals and hard materials, 1994, 12(5): 283-293
Materials Science and Engineering A 486 (2008) 556–561 [19] Zheng X H, Du Y G, Xiao J Y, et al.