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Online since: August 2013
Authors: Guo Li He, Hong Hong Yi, Xiao Long Tang, Fen Rong Li, Yun Dong Li, Kai Li
Materials and Methods
Materials preparation.
Journal of Nuclear Science and Technology, 1965, 2 (2) :51-56
New Carbon Materials.2005,20(4):369-372
Journal of Inorganic Materials. 2006,21(1):81-86
Journal of Inorganic Materials.2004,19(1):177-182
Journal of Nuclear Science and Technology, 1965, 2 (2) :51-56
New Carbon Materials.2005,20(4):369-372
Journal of Inorganic Materials. 2006,21(1):81-86
Journal of Inorganic Materials.2004,19(1):177-182
Online since: December 2017
Authors: A.G. Barbosa de Lima, R.Q. da Costa Melo
Shackelford, Materials Science For Engineers, six. ed., Peason Prentice Hall, New Jersey, 2005
Ashby, Materials and design: art and science of material selection in product design, Elsevier, Rio de Janeiro, 2011 (In Portuguese)
Thesis in Science and Materials Engineering.
Mattoso, Journal Appl.
In Congress on Materials Science of Mercosul.
Ashby, Materials and design: art and science of material selection in product design, Elsevier, Rio de Janeiro, 2011 (In Portuguese)
Thesis in Science and Materials Engineering.
Mattoso, Journal Appl.
In Congress on Materials Science of Mercosul.
Online since: July 2008
Authors: Y.Q. Wang, Shi Chun Yang, Ming Rang Cao, Wen Hui Li, Sheng Qiang Yang
So
under the same single pulse energy, the material with higher thermal conductivity and higher
thermal diffusivity has a larger thermal effect volume than other materials.
Acknowledgements This project is supported by the foundation of Taiyuan science and technology bureau (070204023) References [1] K.H.
Pandey: Journal of Materials Processing Technology, vol. 149 (2004), p.272-277 [3] J.
Tsai: Journal of Materials Processing Technology, vol.87 (1-3) (1999), p. 139-145 [7] J.
Satyanarayana: Journal of Materials Processing Technology 153-154 (1-3) (2004), p. 978-981
Acknowledgements This project is supported by the foundation of Taiyuan science and technology bureau (070204023) References [1] K.H.
Pandey: Journal of Materials Processing Technology, vol. 149 (2004), p.272-277 [3] J.
Tsai: Journal of Materials Processing Technology, vol.87 (1-3) (1999), p. 139-145 [7] J.
Satyanarayana: Journal of Materials Processing Technology 153-154 (1-3) (2004), p. 978-981
Online since: September 2011
Authors: Wei Sun, Xiao Bao Zuo, Xiong Zhou Yuan
Study of feasibility of heat melt adhesive being used in crack self-healing of cement-based materials
Yuan Xiong-zhou1,a, Sun Wei1,b, Zuo Xiao-bao2,c
1College of Materials Science and Engineering, Southeast University, Nanjing, China;
2College of Science, Nanjing University of Science & Technology, Nanjing, China;
acouscous@126.com, bsunwei@seu.edu.cn, cxbzuo@sina.com
Keywords: Self-healing; EVA; PA; Heat-melt adhesive; Feasibility;
Abstract.
Experimental materials EVA heat-melt adhesive was chosen in the experiments, as shown in Figure 1.
S. van der Zwaag (eds.), Self Healing Materials, An Alternative Approach to 20 Centuries of Materials Science, Springer series in materials science 100, Springer Netherlands, 2007, 195–204
Journal of Advanced Concrete Technology, 2006, 4(2): 267–275
Journal of the Chinese Ceramic Society,2010, 38(11):2185-2192
Experimental materials EVA heat-melt adhesive was chosen in the experiments, as shown in Figure 1.
S. van der Zwaag (eds.), Self Healing Materials, An Alternative Approach to 20 Centuries of Materials Science, Springer series in materials science 100, Springer Netherlands, 2007, 195–204
Journal of Advanced Concrete Technology, 2006, 4(2): 267–275
Journal of the Chinese Ceramic Society,2010, 38(11):2185-2192
Online since: January 2015
Authors: Bin Huang, Yi Nian Zhu, Zong Qiang Zhu, Shuang Cao
Keywords: Biomorphic-genetic materials; hydroxyapatite; Activated carbon; Adsorption; heavy metals;
Abstract.
Materials and methods Materials.
Sillanpää: Chemical Engineering Journal.
Ekhe : Chemical Engineering Journal.
Zhu: Advanced Materials Research.
Materials and methods Materials.
Sillanpää: Chemical Engineering Journal.
Ekhe : Chemical Engineering Journal.
Zhu: Advanced Materials Research.
Online since: June 2014
Authors: Zi Yu Wu, Augusto Marcelli, Daniele Di Gioacchino, Sheng Hao Wang
The AC magnetic susceptibility is a fundamental method in materials science, which allows to probe the dynamic magnetic response of magnetic materials and superconductors.
Introduction The AC magnetic susceptibility measurement is a unique method suitable to provide a precise characterization of magnetic and superconducting materials in a non-destructive way, particularly appropriate to study the dynamic magnetic response of a material [1].
(4) A reliable characterization of materials with a non-linear magnetic response requires the measurement of harmonic susceptibilities beyond the fundamental one.
All these characteristics make this instrument particularly suitable to probe weak magnetic phases present in diluted magnetic structures such as antiferromagnet, super paramagnetic systems, spin glass and the transport properties of many complex materials and in particular, to investigate the vortex dynamics of superconductor materials.
Puri, "Experiments on strongly correlated materials under extreme conditions," Graduate School "Vito Volterra", Doctorate in Material Science-XXIV Cycle, Sapienza University of Rome AA2011/12, pp.35-36
Introduction The AC magnetic susceptibility measurement is a unique method suitable to provide a precise characterization of magnetic and superconducting materials in a non-destructive way, particularly appropriate to study the dynamic magnetic response of a material [1].
(4) A reliable characterization of materials with a non-linear magnetic response requires the measurement of harmonic susceptibilities beyond the fundamental one.
All these characteristics make this instrument particularly suitable to probe weak magnetic phases present in diluted magnetic structures such as antiferromagnet, super paramagnetic systems, spin glass and the transport properties of many complex materials and in particular, to investigate the vortex dynamics of superconductor materials.
Puri, "Experiments on strongly correlated materials under extreme conditions," Graduate School "Vito Volterra", Doctorate in Material Science-XXIV Cycle, Sapienza University of Rome AA2011/12, pp.35-36
Online since: June 2014
Authors: Hai Tao Xue, Shan Si Tian, Ai Hua Huang, Min Wang, Zhi Wei Wang, Wen Hua Zhang
This research combines the material balance method and hydrocarbon generation kinetics to calculate the hydrocarbon expulsion efficiency.
Use of material balance principle, we can calculate the hydrocarbon expulsion efficiency(HEE)(as shown in Eq. 2).
Journal of South China University of Technology(Natural Science),1996, 24(supplement):83-87
Review of the calculation of primary migration amount and selection of parameters[J].Earth Science-Journal of China University of Geosciences, 1990,15(1):9-14
Journal of Xinjiang Petroleum Institute,2000,12(3):1-3
Use of material balance principle, we can calculate the hydrocarbon expulsion efficiency(HEE)(as shown in Eq. 2).
Journal of South China University of Technology(Natural Science),1996, 24(supplement):83-87
Review of the calculation of primary migration amount and selection of parameters[J].Earth Science-Journal of China University of Geosciences, 1990,15(1):9-14
Journal of Xinjiang Petroleum Institute,2000,12(3):1-3
Online since: July 2011
Authors: Ze Peng Zhang, Ji Chu Zhang, Xiao Ming Liu, Bo Hu
Preparation and Damping property Study of Styrene-Acrylic IPN/Mt Nano-composite Material
Bo Hu1, a, Zepeng Zhang1, Xiaoming Liu1, Jichu Zhang1
School of Materials Science and Technology, China University of Geoscience,China, 100083
azhangzp@cugb.edu.cn
Keywords: Interpenetrating Polymer Network, damping materials, montmorillonite
Abstract.
Materials Research Bulletin 46 (2011), 124–129 [6] Yongping Dong.
Journal of Luminescence 130 (2010), 1539–1545 [7] Richard Perez Moyet, Yenny Cardonab.
Materials characterization,61 (2010), 1317 – 1325 [8] Deng,Chen.
Materials and Design 32 (2011), 803–807
Materials Research Bulletin 46 (2011), 124–129 [6] Yongping Dong.
Journal of Luminescence 130 (2010), 1539–1545 [7] Richard Perez Moyet, Yenny Cardonab.
Materials characterization,61 (2010), 1317 – 1325 [8] Deng,Chen.
Materials and Design 32 (2011), 803–807
Online since: September 2013
Authors: Volodymyr Hutsaylyuk, Mykola Czausow, Valentin Berezin, Andriy Pylypenko, Lucjan Śnieżek
Classification of materials based on the grain size is problematic due to the lack of experimental data.
At the additional impulse loading of coarse materials an external energy expended on the formation of a dissipative structures, and during testing of fine-grained materials (nano-structures) - on their fracture.
Acknowledgments The authors gratefully acknowledge the funding by National Science Centre of Poland under the grant No.
Estonian Journal of Engineering, Vol. 18(4), (2012), p. 251–258
Scientific Journal of the Ternopil National Technical University, special edition, part 2, (2011), p.92-97
At the additional impulse loading of coarse materials an external energy expended on the formation of a dissipative structures, and during testing of fine-grained materials (nano-structures) - on their fracture.
Acknowledgments The authors gratefully acknowledge the funding by National Science Centre of Poland under the grant No.
Estonian Journal of Engineering, Vol. 18(4), (2012), p. 251–258
Scientific Journal of the Ternopil National Technical University, special edition, part 2, (2011), p.92-97