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Online since: September 2022
Authors: Rozana Aina Maulat Osman, Mohd Sobri Idris, Domingo Arturo Ruiz León, Ku Noor Dhaniah Ku Muhsen, Nur Izzati Muhammad Nadzri, Nadia Nasika Nasir
Journal of Materials Science: Materials in Electronics, 1-13
Journal of Materials Science: Materials in Electronics, 30(20), 18336-18341
Journal of Materials Science: Materials in Electronics, 31(3), 2337-2346
Journal of Materials Science: Materials in Electronics, 30(23), 20673-20686
Journal of Materials Science: Materials in Electronics, 30(8), 7514-7523.
Journal of Materials Science: Materials in Electronics, 30(20), 18336-18341
Journal of Materials Science: Materials in Electronics, 31(3), 2337-2346
Journal of Materials Science: Materials in Electronics, 30(23), 20673-20686
Journal of Materials Science: Materials in Electronics, 30(8), 7514-7523.
Online since: August 2012
Authors: Bo Wang, Hui Lan Sun, Xue Zheng Zhang
The reason for the above change law is that materials expands and shrinks during heating and cooling.
So more energy is absorpted when holding time is longer and the materials expand to larger degree.
Therefore as to materials of the same partical size and leaching conditions, samples of longer holding time have more holes in it.
Journal of Mater Science. 2007, 42(6):1872-1883
Materials Science and Engineering, 2005, 25(5-8): 722-726
So more energy is absorpted when holding time is longer and the materials expand to larger degree.
Therefore as to materials of the same partical size and leaching conditions, samples of longer holding time have more holes in it.
Journal of Mater Science. 2007, 42(6):1872-1883
Materials Science and Engineering, 2005, 25(5-8): 722-726
Online since: June 2011
Authors: Dyi Cheng Chen, Jhih Ming Chen, Chih Hsuan Jao, Wen Jong Chen, Ming Wei Guo
Jolly: Journal of Materials Processing Technology Vol. 135 (2003), p. 189
Jolly: Journal of Materials Processing Technology Vol. 135 (2003), p. 197
Kim: Journal of Materials Processing Technology Vol. 173 (2006), p. 223
Kim: Journal of Materials Processing Technology Vols. 143-144 (2003), p. 729
Shivpuri: Journal of Materials Processing Technology Vol. 150 (2004), p. 70
Jolly: Journal of Materials Processing Technology Vol. 135 (2003), p. 197
Kim: Journal of Materials Processing Technology Vol. 173 (2006), p. 223
Kim: Journal of Materials Processing Technology Vols. 143-144 (2003), p. 729
Shivpuri: Journal of Materials Processing Technology Vol. 150 (2004), p. 70
Online since: July 2011
Authors: Hui Fei Huang, Hang Li Zhang, Hong Yu Wang, Qian Zhao
Experiment materials and methods
Materials.
[3] Wen-Tien Tsai, Chi-Wei Lai, Ting-Yi Su, Journal of Hazardous Materials.
[19] Wen-Tien Tsai, Hsin-Chieh Hsu, Ting-Yi Su, Journal of Colloid and Interface Science.299 (2006) 513–519 [20] L. de Pablo-Galán, M.L.
[23] Wen-Tien Tsai, Hsin-Chieh Hsu, Ting-Yi Su, Journal of Colloid and Interface Science.299 (2006) 513–519 [24] Yi Dong, Deyi Wu, Xuechu Chen, Yan Lin.
Journal of Colloid and Interface Science. 348 (2010) 585–590 [25] G.F.
[3] Wen-Tien Tsai, Chi-Wei Lai, Ting-Yi Su, Journal of Hazardous Materials.
[19] Wen-Tien Tsai, Hsin-Chieh Hsu, Ting-Yi Su, Journal of Colloid and Interface Science.299 (2006) 513–519 [20] L. de Pablo-Galán, M.L.
[23] Wen-Tien Tsai, Hsin-Chieh Hsu, Ting-Yi Su, Journal of Colloid and Interface Science.299 (2006) 513–519 [24] Yi Dong, Deyi Wu, Xuechu Chen, Yan Lin.
Journal of Colloid and Interface Science. 348 (2010) 585–590 [25] G.F.
Online since: May 2011
Authors: Min Yu, Shui Ping Yin
Dynamic mechanical behavior of materials, which is the response under cyclic stress(cyclic strain/force) in vibration condition, is different from its static behavior.
References [1] H Hu, Y D Li, et al.: Journal of Zhengzhou University of Light Industry Vol. 23(2008), p.24 [2] M L Guo.
The dynamic mechanical thermal analysis on polymer and composite materials (Chemical Industry Press, Beijing, 2002)
The mechanical properties of polymers (University of Science and Technology of China Press, Hefei, 2008)
[4] Z G Zhang, C H He, Y B Li, et al.: Polymers & Polymer Composites Vol. 15(2007), p.297 [5] J M Cheng, X Chen, P Zhang: China Elastomerics Vol. 18(2008), p.51 [6] J Yang, S K Li: Chinese Journal of Materials Research Vol. 23(2009), p.524 [7] Information on http://www.tainstruments.com [8] C H He, Z G Zhang, et al.: Acta Materiae Compositae Sinica Vol. 24(2007), p.73 [9] Groves I F, Lever T J, Hawkins N A: International Labmate, Vol.XVII, p.1
References [1] H Hu, Y D Li, et al.: Journal of Zhengzhou University of Light Industry Vol. 23(2008), p.24 [2] M L Guo.
The dynamic mechanical thermal analysis on polymer and composite materials (Chemical Industry Press, Beijing, 2002)
The mechanical properties of polymers (University of Science and Technology of China Press, Hefei, 2008)
[4] Z G Zhang, C H He, Y B Li, et al.: Polymers & Polymer Composites Vol. 15(2007), p.297 [5] J M Cheng, X Chen, P Zhang: China Elastomerics Vol. 18(2008), p.51 [6] J Yang, S K Li: Chinese Journal of Materials Research Vol. 23(2009), p.524 [7] Information on http://www.tainstruments.com [8] C H He, Z G Zhang, et al.: Acta Materiae Compositae Sinica Vol. 24(2007), p.73 [9] Groves I F, Lever T J, Hawkins N A: International Labmate, Vol.XVII, p.1
Online since: March 2014
Authors: Yu Guang Lv, Li Zhang, Kui Lin Lv, Shu Jing Zhou, Du A, Ji Hui Zheng, Peng Jiao, Jia Yu Hou, Yui Zhu
Synthesis, Characterization and Property of Nano Rare Earth Terbium Complex with Gatifloxacin
Yuguang Lv 1, a, Li Zhang1, Kuilin Lv2, Shujing Zhou1, b, Du A1, Jihui Zheng1, Peng Jiao1, JiayuHou1, Yui Zhu1
1 College of Pharmacy, Jiamusi University, Jiamusi 154007, China
2 College of Materials Science and Engineering, Beijing University of Chemical Technology, Beijing 100029, China
a yuguanglv@163.com, b zhshj2003@163.com
Keywords: Nano Rare Earth Complex;Gatifloxacin;Characterization;Luminescence Property; Biological actrivity
Abstract: Rare earth metal complexes have special characteristics, such as extremely narrow emission bands and high internal quantum efficiencies, which are suitable to be used as the emission materials, chemistry and biological technology.
Introduction In recent years, fluorescent materials made from rare earth complexes have generated much research interest in many fields, such as materials science, chemistry, biological technology and information technology[1-4].
Table 2 Inhibition zone diameter of Tb(GFLX)3Phe and GFLX Complex Test results of bacteriostatic ring diameter(mm) Escherichia coli Staphylococcus aureus Tb(GFLX)3Phen(20µg/ pill) 36.22 38.35 GFLX 29.12 30.25 Tb(GFLX)3Phen(10µg/ pill) 27.52 31.66 GFLX 23.35 25.15 Conclusions Rare-earth complex of Tb 3+with GFLX and 1,10-phenanthroline had been synthesized and used as emission materials and antiseptic.
The experiment result shows the complex is stable, and their PL and EL properties were systematically studied by using the complex as emissive material.
[J]Journal of Luminescence. 130(2010):2100–2105 [4] N.
Introduction In recent years, fluorescent materials made from rare earth complexes have generated much research interest in many fields, such as materials science, chemistry, biological technology and information technology[1-4].
Table 2 Inhibition zone diameter of Tb(GFLX)3Phe and GFLX Complex Test results of bacteriostatic ring diameter(mm) Escherichia coli Staphylococcus aureus Tb(GFLX)3Phen(20µg/ pill) 36.22 38.35 GFLX 29.12 30.25 Tb(GFLX)3Phen(10µg/ pill) 27.52 31.66 GFLX 23.35 25.15 Conclusions Rare-earth complex of Tb 3+with GFLX and 1,10-phenanthroline had been synthesized and used as emission materials and antiseptic.
The experiment result shows the complex is stable, and their PL and EL properties were systematically studied by using the complex as emissive material.
[J]Journal of Luminescence. 130(2010):2100–2105 [4] N.
Online since: March 2004
Authors: T.Y. Hsu, Xue Jun Jin, Z.M. Peng, Samuel M. Allen, Robert C. O'Handley
Hsu1
1
School of Materials Science and Engineering, Shanghai Jiao Tong University, Shanghai 200030,
China
2
Department of Materials Science and Engineering, Massachusetts Institute of Technology,
Cambridge, Massachusetts 02139, USA
Keywords: Ni-Mn-Ga, material design, ageing, internal friction
Abstract.
Introduction Ni-Mn-Ga ferromagnetic shape memory alloys (FSMA) are a potential new class of actuator materials able to respond at higher frequencies (at least 300 Hz) with comparable strains (up to 6 %) in a moderate field (below 1 T)[1].
Magnitude of the strain depends on the values of several critical material parameters, most importantly the martensitic transformation temperature (TMart), Curie temperature (TC) and saturation magnetization (MS)[2].
Journal Title and Volume Number (to be inserted by the publisher) 40 50 60 8.50x10-4 9.00x10-4 9.50x10-4 1.00x10-3 1.05x10-3 1.10x10-3 After 40 days As annealed Resistance / ohms Temperature / C 0.000 0.001 0.002 0.003 0.004 Strain Strain Fig. 3 Resistance change during heating-cooling cycles for a Ni-Mn-Ga alloy: a) as-annealed: solid triangle, b) after staying at room temperature for 40 days: open triangle.
The modulus and internal friction directly related to the detail structure of materials are worth further investigating.
Introduction Ni-Mn-Ga ferromagnetic shape memory alloys (FSMA) are a potential new class of actuator materials able to respond at higher frequencies (at least 300 Hz) with comparable strains (up to 6 %) in a moderate field (below 1 T)[1].
Magnitude of the strain depends on the values of several critical material parameters, most importantly the martensitic transformation temperature (TMart), Curie temperature (TC) and saturation magnetization (MS)[2].
Journal Title and Volume Number (to be inserted by the publisher) 40 50 60 8.50x10-4 9.00x10-4 9.50x10-4 1.00x10-3 1.05x10-3 1.10x10-3 After 40 days As annealed Resistance / ohms Temperature / C 0.000 0.001 0.002 0.003 0.004 Strain Strain Fig. 3 Resistance change during heating-cooling cycles for a Ni-Mn-Ga alloy: a) as-annealed: solid triangle, b) after staying at room temperature for 40 days: open triangle.
The modulus and internal friction directly related to the detail structure of materials are worth further investigating.
Online since: August 2011
Authors: Xiang Yuan Dong, Shu Qing Guo
Materials and methods
Production of hydrothermal humification material.
A water solution containing 10 wt% prepared materials was used.
Comparing HTH materials with reference soil revealed that the HTH had important effect on root length.
Fig.3 Root length of the incubated materials Fig.4 Germination index of the incubated materials Fig. 4 showed the changes of GI for three ratio materials.
Journal of Thermal sicience, vol.15 (2006), p. 274-280 [6] S.
A water solution containing 10 wt% prepared materials was used.
Comparing HTH materials with reference soil revealed that the HTH had important effect on root length.
Fig.3 Root length of the incubated materials Fig.4 Germination index of the incubated materials Fig. 4 showed the changes of GI for three ratio materials.
Journal of Thermal sicience, vol.15 (2006), p. 274-280 [6] S.
Online since: December 2010
Authors: Jun Teng, Zuo Hua Li, Xue Feng He
This paper presents a numerical strategy to model nonlinear damage behavior of RC members based on level of material.
For steel material in RC members, we adopt bilinear kinematic hardening model.
Acknowledgements The authors acknowledge the financial support from the National Natural Science Foundation of China under Grant No. 51008048 and 50938001.
Fenves: Journal of Engineering Mechanics, ASCE Vol. 124(1998), p. 892-900 [6] J.
Oller: International Journal of Solids and Structures Vol. 25(1989), p. 299-326
For steel material in RC members, we adopt bilinear kinematic hardening model.
Acknowledgements The authors acknowledge the financial support from the National Natural Science Foundation of China under Grant No. 51008048 and 50938001.
Fenves: Journal of Engineering Mechanics, ASCE Vol. 124(1998), p. 892-900 [6] J.
Oller: International Journal of Solids and Structures Vol. 25(1989), p. 299-326
Online since: March 2015
Authors: Ning Ma, Ke Su Liu, Quan Kun Liu, Yu Jie Ma
Journal of Material Processing Technology [J]. 1996, 60:19-26
[5] Hu Ping, Rate-dependent quasi-flow corner theory for elastic/visco-plastic materials, Int.
Materials Science and Engineering A, 2008, 478: 130-139
Material Science and Technology, 2008, 162:172-175
Transactions of Materials and Heat Treatment, 2010, 13:33-36.
[5] Hu Ping, Rate-dependent quasi-flow corner theory for elastic/visco-plastic materials, Int.
Materials Science and Engineering A, 2008, 478: 130-139
Material Science and Technology, 2008, 162:172-175
Transactions of Materials and Heat Treatment, 2010, 13:33-36.