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Online since: November 2013
Authors: Tu Gen Feng, Cai Yang
Acknowledgements
This work was financially supported by Natural Science Foundation (51009054), The Ministry of Education, Science and Technology Research Projects(109077) and The Natural Science Foundation of Jiangsu Province (BE2010513)
References
[1] ZHAO Shangyi,ZHENG Yingren,SHI Weimin,et.Analusis of safety factor of slope stability by strength reduction FEM[J].Chinese.Journal of Geotechnical Engineering,2002,24(3):343-346(in Chinese)
[2] YIN Zongzhe,et.
Chinese.Journal of Geotechnical Engineering,2002,24(5):626-628 [5] Zienkiewicz O C, Humpheson C, Lewis R W.
Journal Geotechnical Engineering, ASCE, 1996, 122(7): 577-596
[7] LV Qing,SUN Hongyue,SHANG Yuequan.Slope failure criteria of shear strength reduction finite element method[J].Journal of Zhejiang University(Engineering Science),2008,42(1):83-87 [8] ZHAO Shangyi,ZHENG Yingren,ZHANG Yufang.Study on slope failure criterion in strength reduction finite element method[J].Rock and Soil Mechanics,2005,26,(2):332-336 [9] CHEN Zhibo,JIAN Wenbin.Sensibility analysis of slopes stability based on grey correlation analysis[J].Journal of Disaster Prevention and Mitigation Engineering,2006,26(4):474-477 [10] FEI Kang,ZHANG Jianwei.
Chinese.Journal of Geotechnical Engineering,2001,23(4):407-411(in Chinese)
Chinese.Journal of Geotechnical Engineering,2002,24(5):626-628 [5] Zienkiewicz O C, Humpheson C, Lewis R W.
Journal Geotechnical Engineering, ASCE, 1996, 122(7): 577-596
[7] LV Qing,SUN Hongyue,SHANG Yuequan.Slope failure criteria of shear strength reduction finite element method[J].Journal of Zhejiang University(Engineering Science),2008,42(1):83-87 [8] ZHAO Shangyi,ZHENG Yingren,ZHANG Yufang.Study on slope failure criterion in strength reduction finite element method[J].Rock and Soil Mechanics,2005,26,(2):332-336 [9] CHEN Zhibo,JIAN Wenbin.Sensibility analysis of slopes stability based on grey correlation analysis[J].Journal of Disaster Prevention and Mitigation Engineering,2006,26(4):474-477 [10] FEI Kang,ZHANG Jianwei.
Chinese.Journal of Geotechnical Engineering,2001,23(4):407-411(in Chinese)
Online since: July 2011
Authors: Jin Chen, Fu De Nie, Li Li Wang, Guang Cheng Yang
Fabrication and Characterization of YAG Nanopowders by Co-Precipitation under Ultrasonic Radiation
Lili Wang1, 2, a, Jin Chen2, b, Guangcheng Yang2, c, Fude Nie2, d, *
1School of Material Science and Engineering, Southwest University of Science and Technology, mianyang, Sichuan, 621010, China
2China Institute of Chemical Materials, China Academy of Engineering Physics,
Mianyang, Sichuan, 621900, China
ashanowwin@yahoo.cn, bciyeying@yahoo.com.cn, cygcheng@hotmail.com, dzgh-nfd@sohu.com
Keywords: Ultrasonic, YAG nanopowders, Co-Precipitation, Fabrication.
Optical Materials 31 (2008) 6-17
Optical Materials 29 (2007) 1289-1294
Materials Letters 61 (2007) 921–924
Energetic Materials. 2003,11 (2) 107-109.
Optical Materials 31 (2008) 6-17
Optical Materials 29 (2007) 1289-1294
Materials Letters 61 (2007) 921–924
Energetic Materials. 2003,11 (2) 107-109.
Online since: January 2014
Authors: Justine M. Kalaw, Fortunato B. Sevilla, Rey Alfred G. Rañola
The addition of graphene as filler or as a platform improves the physico-chemical and electrical properties of conventional polymer materials.
In addition it enables to attain a low percolation threshold at lower loading fractions compared to other carbon materials[4].
Therefore it uses less amount of conducting filler and cheaper in contrast to other carbon particle materials.
Methodology Reagents and Materials.
Biological and chemical sensors based on graphene materials.
In addition it enables to attain a low percolation threshold at lower loading fractions compared to other carbon materials[4].
Therefore it uses less amount of conducting filler and cheaper in contrast to other carbon particle materials.
Methodology Reagents and Materials.
Biological and chemical sensors based on graphene materials.
Online since: August 2018
Authors: Rui Zhang, Bing Bing Fan, Yong Qiang Chen, Sai Li, Wei Li, Ting Ting Su, Hong Xia Li
Microwave sintering promoted the density of materials by materials dielectric loss absorbing microwave[3].
Microwave is absorbed selectively by different materials at related temperature which leads to the phenomenon[15].
Hejazi, Processing of nanocrystalline 8mol% yttria-stabilized zirconia by conventional, microwave-assisted and two-step sintering, Materials Science & Engineering A, 492 (2008) 261-267
Ohji, Fabrication of porous Al2O3 by microwave sintering and its properties, Materials Letters, 48 (2001) 215-218
Stevens, Zirconia-toughened alumina (ZTA) ceramics, Journal of Materials Science, 24 (1989) 3421-3440
Microwave is absorbed selectively by different materials at related temperature which leads to the phenomenon[15].
Hejazi, Processing of nanocrystalline 8mol% yttria-stabilized zirconia by conventional, microwave-assisted and two-step sintering, Materials Science & Engineering A, 492 (2008) 261-267
Ohji, Fabrication of porous Al2O3 by microwave sintering and its properties, Materials Letters, 48 (2001) 215-218
Stevens, Zirconia-toughened alumina (ZTA) ceramics, Journal of Materials Science, 24 (1989) 3421-3440
Online since: November 2013
Authors: Duvvuri Subbarao, Maizatul Shima Shaharun, A. Naeem, Israf Ud Din
Methanol has been synthesized by various starting materials.
Similarly, catalyst particles loading is dependent on many factors including nature of adsorption sites, pH of the solution and starting materials.
Studies in Surface Science and Catalysis, Elsevier, 1995, pp. 263-271
Studies in Surface Science and Catalysis, Elsevier, 1979, pp. 113-130
Studies in Surface Science and Catalysis, Elsevier, 1991, pp. 19-36
Similarly, catalyst particles loading is dependent on many factors including nature of adsorption sites, pH of the solution and starting materials.
Studies in Surface Science and Catalysis, Elsevier, 1995, pp. 263-271
Studies in Surface Science and Catalysis, Elsevier, 1979, pp. 113-130
Studies in Surface Science and Catalysis, Elsevier, 1991, pp. 19-36
Online since: August 2019
Authors: Irwan Lie Keng Wong, Atus Buku, Josefine Ernestine Latupeirissa, Herby Calvin Pascal Tiwouy
The waterwheel from the drum material is simple and easy to make and the material is easy to obtain.
The waterwheel is made using 6 mm iron which is shaped like a bicycle rim, while the pinwheel blade is made using Acrylic materials made with the following steps: Iron with a diameter of 6 mm cut and then formed a circle with a diameter of 44 cm as much as 2 pieces, the connecting process using weld.
For blades made of Acrylic material which is cut.
Australian Journal of Basic and Applied Sciences, 8, 6, 186-192
Science-Technology Controversy.
The waterwheel is made using 6 mm iron which is shaped like a bicycle rim, while the pinwheel blade is made using Acrylic materials made with the following steps: Iron with a diameter of 6 mm cut and then formed a circle with a diameter of 44 cm as much as 2 pieces, the connecting process using weld.
For blades made of Acrylic material which is cut.
Australian Journal of Basic and Applied Sciences, 8, 6, 186-192
Science-Technology Controversy.
Online since: October 2016
Authors: Chen Li, Fei Hu Zhang, Xiao Shuang Rao
Experimetal procedure
Equipment and materials.
Materials and Manufacturing Process. 25 (2010) 851-856
Materials and Manufacturing Processes. 28 (2013) 381-389
Journal of Materials Technology. 191 (2007) 206-209
Journal of Mechanical Science & Technology, 27 (2013) 177-183.
Materials and Manufacturing Process. 25 (2010) 851-856
Materials and Manufacturing Processes. 28 (2013) 381-389
Journal of Materials Technology. 191 (2007) 206-209
Journal of Mechanical Science & Technology, 27 (2013) 177-183.
Online since: February 2015
Authors: Jing Yang, Han Zhou Sun, Wen Jie Ma, Jin Hua Zhou, Ni Li
Choi, et al: Journal of Applied Polymer Science, Vol. 111 (4) (2009), p. 1828
[4] S.J.
Zhang, et al: Journal of Colloid and Interface Science, Vol. 361 (2) (2011), p. 483 [7] N.G.
Can, et al: Journal of Applied Polymer Science, Vol. 82 (3) (2001), p. 703 [23] C.
Wu, et al: Advanced Materials Research, Vol. 418-420 (2012) p. 693 [25] X.F.
Zhou, et al: Advanced Materials Research, Vol. 554-556 (2012), p. 191
Zhang, et al: Journal of Colloid and Interface Science, Vol. 361 (2) (2011), p. 483 [7] N.G.
Can, et al: Journal of Applied Polymer Science, Vol. 82 (3) (2001), p. 703 [23] C.
Wu, et al: Advanced Materials Research, Vol. 418-420 (2012) p. 693 [25] X.F.
Zhou, et al: Advanced Materials Research, Vol. 554-556 (2012), p. 191
Online since: March 2011
Authors: Hui Huang, Xi Peng Xu, Guo Qin Huang, Cong Fu Fang, X.H. Yu, H. Guo
This might be related to the different material removal mechanisms for two kinds of materials.
In grinding of ceramic, materials dominantly removes in brittle mode.
Shi.: Grinding of Difficult-to-cut Materials.
Huang and etal.: Journal of Mechanical Engineering, Vol.45, 2009(3), pp:100-114 [7] X.M.
Journal of Materials Processing Technology, Vol.210 (2010), pp: 899–906
In grinding of ceramic, materials dominantly removes in brittle mode.
Shi.: Grinding of Difficult-to-cut Materials.
Huang and etal.: Journal of Mechanical Engineering, Vol.45, 2009(3), pp:100-114 [7] X.M.
Journal of Materials Processing Technology, Vol.210 (2010), pp: 899–906