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Online since: October 2011
Authors: Roy Paily Palathinkal, N. Ramakrishnan, Harshal B. Nemade
When exposed to UV, SU-8's long molecular chains cross-link causes solidification of the material.
The materials, method used in the experiments and results on the morphology of the fabricated SU-8 pillars on piezoelectric substrates and SAW transducers are presented in the following sections.
Materials and Method Several trials are carried out to optimize the recipe to fabricate HAR SU-8 pillars on Lithium Niobate and Aluminium substrates.
Gale: Journal of Micromechanics and Microengineering Vol. 8 (2008), p. 045021
Palathinkal: IEEE Sensor Journal Vol. 11 (2011), p.430
The materials, method used in the experiments and results on the morphology of the fabricated SU-8 pillars on piezoelectric substrates and SAW transducers are presented in the following sections.
Materials and Method Several trials are carried out to optimize the recipe to fabricate HAR SU-8 pillars on Lithium Niobate and Aluminium substrates.
Gale: Journal of Micromechanics and Microengineering Vol. 8 (2008), p. 045021
Palathinkal: IEEE Sensor Journal Vol. 11 (2011), p.430
Online since: May 2012
Authors: Bo Chen, Zeng Guo Jiang
The density of the beam material is and the Young’s modulus is.
Amand: Wavelet-based approach for structural damage detection, Journal of Engineering Mechanics, ASCE, 2000, 126(7), p. 677-683
Farrar: Holder exponent analysis for discontinuity detection, Journal of Structural Engineering and Mechanics ASCE, 2004, 17 (3-4), p.409-428
Chen, Y.L.Xu: A new damage index for detecting sudden change of structural stiffness, International Journal of Structural Engineering and Mechanics, 2007, 26(3): p. 315-341
Advanced Materials Research, 2011, 150-151: p.1580-1583.
Amand: Wavelet-based approach for structural damage detection, Journal of Engineering Mechanics, ASCE, 2000, 126(7), p. 677-683
Farrar: Holder exponent analysis for discontinuity detection, Journal of Structural Engineering and Mechanics ASCE, 2004, 17 (3-4), p.409-428
Chen, Y.L.Xu: A new damage index for detecting sudden change of structural stiffness, International Journal of Structural Engineering and Mechanics, 2007, 26(3): p. 315-341
Advanced Materials Research, 2011, 150-151: p.1580-1583.
Online since: January 2012
Authors: Cheng Jiang Lu, Hong Bin Zhao
Material plasticity should be avoided, since it would reduce the load-bearing capacity in the deployed configuration.
The material must remain linearly elastic, so that there will be no residual stresses to reduce the load bearing capacity under service load.
International Journal of Space Structures.
International Journal of Space Structures.
International Journal of Space Structures.
The material must remain linearly elastic, so that there will be no residual stresses to reduce the load bearing capacity under service load.
International Journal of Space Structures.
International Journal of Space Structures.
International Journal of Space Structures.
Online since: February 2014
Authors: Zhen Hua Li, She Ming Jiang, Qi Fu Zhang, Shi Jie Feng
Materials Science and Engineering: A, 2008. 491(1): p. 39-46
Materials science and technology, 2003. 19(1): p. 125-131
The Journal of Physical Chemistry, 1984, 88(21): 4922-4929
Journal of iron and Steel Research. 2012. 24(5): p.29-34
Materials Science and Engineering: A, 2007. 463(1): p. 147-156
Materials science and technology, 2003. 19(1): p. 125-131
The Journal of Physical Chemistry, 1984, 88(21): 4922-4929
Journal of iron and Steel Research. 2012. 24(5): p.29-34
Materials Science and Engineering: A, 2007. 463(1): p. 147-156
Online since: July 2011
Authors: Xing Chang Tang, Yan Yan Bo, Lei Fan, Yong Lin Kang
Iordachescu: Materials and Design, 30 (2009) 2701-2707
Wei, S.Yyin, Y.Ke. : Materials Science and Engineering A, 502 (2009):38-44
[7] Bakkaloǧlu. : Materials Letters, 56 (2002):263-272
[8] Hwang, C.G.Lee: Materials Science and Engineering A 527 (2010), 4341-4346
[9] S.Y.Shin, S.Y.Han, B.Hwang, C.G.Lee, S.Lee: Materials Science and Engineering A 517(2009), 212-218.
Wei, S.Yyin, Y.Ke. : Materials Science and Engineering A, 502 (2009):38-44
[7] Bakkaloǧlu. : Materials Letters, 56 (2002):263-272
[8] Hwang, C.G.Lee: Materials Science and Engineering A 527 (2010), 4341-4346
[9] S.Y.Shin, S.Y.Han, B.Hwang, C.G.Lee, S.Lee: Materials Science and Engineering A 517(2009), 212-218.
Online since: March 2018
Authors: Chih Ling Huang, Wei Wen Lin, Wei Fang, Tze Yo Hung, I Hao Chen
Materials and Methods
BG samples were produced through sol-gel method.
Acknowledgments The authors gratefully acknowledge the financial support provided to this study by the Ministry of Science and Technology (MOST) in Taiwan under Grant Nos.
Boccaccini: “Sol-gel processing of bioactive glass nanoparticles: A review,” Advances in Colloid and Interface Science (2017), p. 1-11 [3] Julian R.
Knowles: “Sol–gel based materials for biomedical applications,” Progress in Materials Science (2017), Vol. 77, p. 1-79 [5] Z.
Jing, “Preparation of bioactive glass ceramic nanoparticles by combination of sol–gel and coprecipitation method,” Journal of Non-Crystalline Solids, (2009), Vol. 355, p. 368-372
Acknowledgments The authors gratefully acknowledge the financial support provided to this study by the Ministry of Science and Technology (MOST) in Taiwan under Grant Nos.
Boccaccini: “Sol-gel processing of bioactive glass nanoparticles: A review,” Advances in Colloid and Interface Science (2017), p. 1-11 [3] Julian R.
Knowles: “Sol–gel based materials for biomedical applications,” Progress in Materials Science (2017), Vol. 77, p. 1-79 [5] Z.
Jing, “Preparation of bioactive glass ceramic nanoparticles by combination of sol–gel and coprecipitation method,” Journal of Non-Crystalline Solids, (2009), Vol. 355, p. 368-372
Online since: July 2005
Authors: Wei Min Mao, Ping Yang, Zude Zhao, Li Meng
Experimental procedure
Hot-rolled magnesium alloy AZ31 sheet was chosen as the initial material.
The material was annealed at 500℃ for 3h in order to obtain mean equiaxed grains (~25µm).
Tan: Materials Science and Engineering Vol.A339(2003), p.81 [2] Kaibyshev, I.V.
Zaripov: Journal of materials science Vol.23(1988), p.4369 [3] J.
Maruyama: Materials Transactions Vol.44(2003), p.445 [4] Y.N.Wang, J.C.Huang: Scripta Mater.
The material was annealed at 500℃ for 3h in order to obtain mean equiaxed grains (~25µm).
Tan: Materials Science and Engineering Vol.A339(2003), p.81 [2] Kaibyshev, I.V.
Zaripov: Journal of materials science Vol.23(1988), p.4369 [3] J.
Maruyama: Materials Transactions Vol.44(2003), p.445 [4] Y.N.Wang, J.C.Huang: Scripta Mater.
Online since: January 2012
Authors: Jia Xiang Liu, Yuan Yu, Li Ping Gao
In the present study, a turbo air classifier is used as the classification system and fine talc powder is used as materials.
Turbo air classifier is the common dry classification device for building materials.
Assuming that the frequency distribution curve of the raw materials and the frequency distribution curve of the coarse powders are known, the mass of the raw materials and coarse powders are written as ωf and ωb in the granularity interval (di and di+Δdi), respectively.
The particle-size distribution of materials is showed as Table 1.
International Journal of Mineral Processing. 2009.92 (6):22-33
Turbo air classifier is the common dry classification device for building materials.
Assuming that the frequency distribution curve of the raw materials and the frequency distribution curve of the coarse powders are known, the mass of the raw materials and coarse powders are written as ωf and ωb in the granularity interval (di and di+Δdi), respectively.
The particle-size distribution of materials is showed as Table 1.
International Journal of Mineral Processing. 2009.92 (6):22-33
Online since: May 2012
Authors: Yong Duo Liang, Zhi Guo Sun, Gong Cai Chi, Yue Jiang, Jin Zheng Jiang
Acknowledgements
This work was financially supported by the National Natural Science Fund(50978042) and Graduate Fund of Earthquake Administration of Liaoning(LZ201205).
Journal of Building Materials, 2000,3(2),p98-102(In Chinese) [2] Zhaohui Luo, Jingling Li, Yupei Zhang.
Journal of Dalian University of Technology, 2011,51(4),p.567-573(In Chinese) [7] Yuahong He.
Course of Study on Grey System Theory [M].Wuhan:Huazhong University of Science and Technology Press,1992.
Research on the Equivalent Plastic Hinge Length of Reinforced Concrete Bridge Columns[J].China Journal of Highway and Transport, 2011,24(2), p.56-64(In Chinese)
Journal of Building Materials, 2000,3(2),p98-102(In Chinese) [2] Zhaohui Luo, Jingling Li, Yupei Zhang.
Journal of Dalian University of Technology, 2011,51(4),p.567-573(In Chinese) [7] Yuahong He.
Course of Study on Grey System Theory [M].Wuhan:Huazhong University of Science and Technology Press,1992.
Research on the Equivalent Plastic Hinge Length of Reinforced Concrete Bridge Columns[J].China Journal of Highway and Transport, 2011,24(2), p.56-64(In Chinese)
Online since: October 2012
Authors: Wen Sheng Dong, Xiu Fang Jiang, Ying Ying Zai, Xian Feng He
[2] Ning Qian, Zhaohui Wan, Mechanics of sediment transport, Science Press, 2003 (In Chinese)
[3] Longyuan Cheng, Cheng Zhang, Yaner Liu, Journal of Sediment Research, 2005, (4): 21~29
[7] Qiwei Han, Journal of Sediment Research, 2005,(4):5~28
[8] Jinliang Zhang, Jijian Lian, Yujie Wang, Yellow River, 2002,24(8):30~33 [9] Shangfu Kuang, Yongnian Xu, Wenbin Li, Study for "Ripping up the bottom” phenomenon and mechanics under hyper-concentrated flood, Symposium Proceedings of the second National Sediment basic theoretical reseach, China Building Materials Industry Press, 1995: 408-419 [10] Enhui Jiang, Yongtao Cao, Qing Zhang, Research present situation of "Ripping up the bottom” in the Yellow River, Yellow River, 2004, 7
(In chinese) [13] Li Haifang, Journal of North China Institute of Water Conservancy and Hydroelectric Power, 1997, 18 (1): 26~31
[3] Longyuan Cheng, Cheng Zhang, Yaner Liu, Journal of Sediment Research, 2005, (4): 21~29
[7] Qiwei Han, Journal of Sediment Research, 2005,(4):5~28
[8] Jinliang Zhang, Jijian Lian, Yujie Wang, Yellow River, 2002,24(8):30~33 [9] Shangfu Kuang, Yongnian Xu, Wenbin Li, Study for "Ripping up the bottom” phenomenon and mechanics under hyper-concentrated flood, Symposium Proceedings of the second National Sediment basic theoretical reseach, China Building Materials Industry Press, 1995: 408-419 [10] Enhui Jiang, Yongtao Cao, Qing Zhang, Research present situation of "Ripping up the bottom” in the Yellow River, Yellow River, 2004, 7
(In chinese) [13] Li Haifang, Journal of North China Institute of Water Conservancy and Hydroelectric Power, 1997, 18 (1): 26~31