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Online since: November 2011
Authors: Wei Li, Sheng Hui Guo, Li Bo Zhang, Jin Hui Peng, Biao Yang, Li Jun Liu, Shi Min Zhang
It finds application as high temperature refractory materials, grinding materials and high temperature insulation materials [4].
PSZ also has a characteristic of materials and thermal shock resistance of refractory materials [5].
Materials Characterization.
Materials Science and Engineering.
Materials Science and Engineering.
PSZ also has a characteristic of materials and thermal shock resistance of refractory materials [5].
Materials Characterization.
Materials Science and Engineering.
Materials Science and Engineering.
Online since: January 2011
Authors: Jing Yang, Ji Yong Du, Shui Bo Xie, Kun Du, Ji Na Song, Zhi Wei Lv
Introduction
Long-lived radionuclides of the 238U series are highly hazardous materials due to their high radioactivity and toxicity.
An alternative process is biosorption, which utilizes various natural materials of biological origin, including bacteria, fungi, yeast, algae, etc. [1-3].
Materials and methods Bacterial strains and cultivation The strain of C. freudii used in this study was provided by the China General Microbiological Culture Collection Center (CGMCC), Chinese Academy of Sciences.
Advances in Environmental Science 5 (6),34-43
Journal of Xiamen University(Natural Science) 42 (2), 233-237
An alternative process is biosorption, which utilizes various natural materials of biological origin, including bacteria, fungi, yeast, algae, etc. [1-3].
Materials and methods Bacterial strains and cultivation The strain of C. freudii used in this study was provided by the China General Microbiological Culture Collection Center (CGMCC), Chinese Academy of Sciences.
Advances in Environmental Science 5 (6),34-43
Journal of Xiamen University(Natural Science) 42 (2), 233-237
Online since: August 2015
Authors: A.P. Gnana Prakash, N. Pushpa
The bandgap energy, minimum energy required to create an electron-hole (e-h) pair, and e-h pair density in different materials used in semiconductor devices.
The linear energy transfer (Se and Sn) and range of different ions in different materials is tabulated in table 2.
The in-situ experimental set-up at Material Science Beam Line, IUAC, New Delhi is shown in figure 9.
(a) A view of in-situ experimental set-up at material science beam line, IUAC, New Delhi.
Fleischer, Ion Tracks in Solids: From Science to Technology to Diverse Applications, MRS Bulletin-Materials Research Society 20 (1995) 17-21
The linear energy transfer (Se and Sn) and range of different ions in different materials is tabulated in table 2.
The in-situ experimental set-up at Material Science Beam Line, IUAC, New Delhi is shown in figure 9.
(a) A view of in-situ experimental set-up at material science beam line, IUAC, New Delhi.
Fleischer, Ion Tracks in Solids: From Science to Technology to Diverse Applications, MRS Bulletin-Materials Research Society 20 (1995) 17-21
Online since: October 2011
Authors: Xiang Zhao, She Liang Wang, Xi Cheng Zhao, Jian Bo Dai
With the development of science and technology and social progress, long-span space structures have made extensive application at home and abroad.
Giant Magnetostrictive Material (known as GMM) is a kind of new intelligent materials, its length and volume will change and the external power will be produced under the action of the magnetic field, and it can return to its original size after removing the external magnetic field, such performance can effectively achieve the conversion between electromagnetic energy and mechanical energy, so it is an important conversion function materials of energy and information[2].
Acknowledgements The Project Supported by Natural Science Basic Research Plan in Shaanxi Province of China (Program No. 2009JQ7005);Ph.D.
Beijing: Science press, China,2003:1-2(In Chiese) [2] Mei LI, Yin-fang LV.
Giant magnetostrictive material and its application [J].
Giant Magnetostrictive Material (known as GMM) is a kind of new intelligent materials, its length and volume will change and the external power will be produced under the action of the magnetic field, and it can return to its original size after removing the external magnetic field, such performance can effectively achieve the conversion between electromagnetic energy and mechanical energy, so it is an important conversion function materials of energy and information[2].
Acknowledgements The Project Supported by Natural Science Basic Research Plan in Shaanxi Province of China (Program No. 2009JQ7005);Ph.D.
Beijing: Science press, China,2003:1-2(In Chiese) [2] Mei LI, Yin-fang LV.
Giant magnetostrictive material and its application [J].
Online since: October 2009
Authors: Rong Chang Liu, Li Dong Chen, Yu Wu, Shu Ying Ma, Li Zhen Feng
In this region, metal will generate a serious lattice distortion, and the mechanical properties
of materials will also be changed.
Acknowledgment This research is supported by National Natural Science Foundation of China(grant No.50675060) and Natural Science Research Program of Hebei Educational Committee (grant No.2008152 ).
Dong, Vol. 14(2007) of Journal of Iron and Steel Research International, chapter, 1, p. 132-136
Wang: Materials Mechanical Properties (Tianjin University Press, Tianjin, 2007)
Shu: Mechanical Properties of Engineering Materials (Mechanical Industry Press, Beijing, 2003)
Acknowledgment This research is supported by National Natural Science Foundation of China(grant No.50675060) and Natural Science Research Program of Hebei Educational Committee (grant No.2008152 ).
Dong, Vol. 14(2007) of Journal of Iron and Steel Research International, chapter, 1, p. 132-136
Wang: Materials Mechanical Properties (Tianjin University Press, Tianjin, 2007)
Shu: Mechanical Properties of Engineering Materials (Mechanical Industry Press, Beijing, 2003)
Online since: January 2012
Authors: Xavier Kleber, Coline Beal, Mohamed Bouzekri, Damien Fabrègue
Experimental procedures
Materials
A Fe-Mn-C TWIP steel was supplied by Arcelor-Mittal Research SA Maizières.
Bouaziz, Materials Science and Engineering A 387–389 (2004) p. 143–147 [3] D.
Humbert, Materials Science and Engineering A 500 (2009) p. 196–206 [4] B.
Foct, Journal of Nuclear Materials 296 (2001) p. 256-264 [11] R.W.
Dillon, Liquid Metal Cracking of Stainless Steels in Chemical Plants, Materials Performance, Vol. 29, No. 11, 1990, p.54-55 [13] D.W.
Bouaziz, Materials Science and Engineering A 387–389 (2004) p. 143–147 [3] D.
Humbert, Materials Science and Engineering A 500 (2009) p. 196–206 [4] B.
Foct, Journal of Nuclear Materials 296 (2001) p. 256-264 [11] R.W.
Dillon, Liquid Metal Cracking of Stainless Steels in Chemical Plants, Materials Performance, Vol. 29, No. 11, 1990, p.54-55 [13] D.W.
Online since: October 2015
Authors: Gisela Lanza, Sebastian Greinacher
Over the last years, worldwide growth of population accompanied by increasing demand of resources has resulted in rising prices for energy and materials.
Despite the necessity for more efficient use of energy and materials in manufacturing, companies face manifold obstacles during implementation of corresponding green strategies.
Production factors include material (raw materials, operating materials, and consumables), energy (electrical, mechanical, chemical, thermal, and others), personnel, and manufacturing equipment.
The presented methodology is part of an ongoing research project at wbk Institute of Production Science.
Official Journal of the European Union, L 140/1, 23.04.2009
Despite the necessity for more efficient use of energy and materials in manufacturing, companies face manifold obstacles during implementation of corresponding green strategies.
Production factors include material (raw materials, operating materials, and consumables), energy (electrical, mechanical, chemical, thermal, and others), personnel, and manufacturing equipment.
The presented methodology is part of an ongoing research project at wbk Institute of Production Science.
Official Journal of the European Union, L 140/1, 23.04.2009
Online since: June 2011
Authors: Liang Dong
Currently, the key and advantageous industries in many cities in China all consist of automobiles, new materials, new energy, environmental protection and electronic information, so does the ones in Wuhan.
In recent years, the main industries such as transportation equipment manufacturing, ferrous metal smelting, communication equipments, electronic information, electric machinery, etc will keep steady increase and the strategic emerging ones with great rise potentiel as recycling process of the rejected or used materials, food and drinks making and agricultural product processing, new energies, new materials, biomedicals, and laser making, etc should be encouraged.
To respond to the fierce competition, the industrial enterprises must strengthen the study on the production technology and on the product varieties by closely cooperating with the scientific institutes, and colleges and universities, and seek for a optimum combination among materials, technology, and performance in order to implement the upgrade of the industrial production and to promote the adoption of the new product in the market and to reach the aim of high efficiency, short processing period and low production costs.
References [1] Zhang Huixin, Du Yueping, Analysis of the RIS Model and of the Location Quotient on the Industrial Clusters of the Shanbei Resources, Resource Science, 2009(7), P1215-1210 [2] Gong Tao, Evaluation of the Location Quotient to the Tertiary Industry in Anhui Province,Coastal Enterprises and Science and Technology, 2008(1), P111-112
Harvard Business Review, 1998,76(6), P 77~90 [8] Zhu Yingming, Analysis on the Industrial Clusters in China, Beijing: Science Press (2006)
In recent years, the main industries such as transportation equipment manufacturing, ferrous metal smelting, communication equipments, electronic information, electric machinery, etc will keep steady increase and the strategic emerging ones with great rise potentiel as recycling process of the rejected or used materials, food and drinks making and agricultural product processing, new energies, new materials, biomedicals, and laser making, etc should be encouraged.
To respond to the fierce competition, the industrial enterprises must strengthen the study on the production technology and on the product varieties by closely cooperating with the scientific institutes, and colleges and universities, and seek for a optimum combination among materials, technology, and performance in order to implement the upgrade of the industrial production and to promote the adoption of the new product in the market and to reach the aim of high efficiency, short processing period and low production costs.
References [1] Zhang Huixin, Du Yueping, Analysis of the RIS Model and of the Location Quotient on the Industrial Clusters of the Shanbei Resources, Resource Science, 2009(7), P1215-1210 [2] Gong Tao, Evaluation of the Location Quotient to the Tertiary Industry in Anhui Province,Coastal Enterprises and Science and Technology, 2008(1), P111-112
Harvard Business Review, 1998,76(6), P 77~90 [8] Zhu Yingming, Analysis on the Industrial Clusters in China, Beijing: Science Press (2006)
Online since: April 2015
Authors: Han Jun Wei, Wan Chang Sun, Guan Qun Hou, Feng Zhang, Qin Shi
Application of Artificial Neural Networks to Optimize Processing- Properties of Ni-TiC Composite Coatings
Hanjun Weia, Wanchang Sunb*, Guanqun Hou, Feng Zhang and Qin Shi
College of Materials Science and Engineering, Xi’an University of Science and Technology,
Xi’an, Shaanxi 710054, China
ajunjun93214@126.com, b*sunwanchang@tsinghua.org.cn
Keywords: Pulse electrodeposition, Composite coating, BP neural network, Orthogonal test.
Hence, BP has been widely applied to the field of materials in recent years.
Neural Networks for Applied Sciences and Engineering-From Fundamentals to Complex Pattern Recognition[M].
Journal of Functional Materials. 2004(35):383-388(in Chinese)
Materials and Design. 2013(45):323-335
Hence, BP has been widely applied to the field of materials in recent years.
Neural Networks for Applied Sciences and Engineering-From Fundamentals to Complex Pattern Recognition[M].
Journal of Functional Materials. 2004(35):383-388(in Chinese)
Materials and Design. 2013(45):323-335
Online since: August 2013
Authors: Shu Hao Huo, Zhao Qin Ma, Xue Jing Zheng
Two Automatic Lime Metering Systems Used in Municipal Reclaimed Water Treatment of Fossil-fueled Power Plant
Shuhao Huo1, a, Xuejing Zheng*2,b and Zhaoqin Ma1,c
1 Henan Electric Power Survey & Design Institute, Zhengzhou 450007, China
2 College of Materials Science and Engineering, Zhengzhou University, Zhengzhou 450052, China
ahuoshuhaozxj@126.com, bx.zheng@zzu.edu.cn, cmazhaoqin10@gmail.com
*Corresponding author: Xuejing Zheng
Keywords: Lime Metering System, Fossil-fueled Power Plant, Metering in Dry Condition, Metering in Wet Condition, Municipal Reclaimed Water.
References [1] Shuhao Huo, Xuejing Zheng, Zhaoqin Ma: Advanced Materials Research Vol. 356-360 (2012), p. 2182 [2] Shuhao Huo, Xuejing Zheng, Zhaoqin Ma: Advanced Materials Research Vol. 518-523 (2012), p. 3744 [3] T.
Ayoub: Advanced in Environmental Research Vol. 7 (2003), p. 389 [6] Dong-jing Choi, Seung-Jae You, Jung-Gu Kim: Materials Science and Engineering: A.
Ataei: International Journal of Environmental Science and Technology Vol. 5 (2008), p. 251 [8] G.
Ayora: Environmental Engineering Science Vol. 25 (2008), p. 43 [9] F.
References [1] Shuhao Huo, Xuejing Zheng, Zhaoqin Ma: Advanced Materials Research Vol. 356-360 (2012), p. 2182 [2] Shuhao Huo, Xuejing Zheng, Zhaoqin Ma: Advanced Materials Research Vol. 518-523 (2012), p. 3744 [3] T.
Ayoub: Advanced in Environmental Research Vol. 7 (2003), p. 389 [6] Dong-jing Choi, Seung-Jae You, Jung-Gu Kim: Materials Science and Engineering: A.
Ataei: International Journal of Environmental Science and Technology Vol. 5 (2008), p. 251 [8] G.
Ayora: Environmental Engineering Science Vol. 25 (2008), p. 43 [9] F.