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Online since: October 2011
Authors: Mohd Hamdi Bin Abd Shukor, Sharifah Adzila Syed Abu Bakar, Iis Sopyan
Wang: Materials Science and Engineering Vol. 20 (2002), p.101-109
[8] D.
Shinomiya Materials Science and Engineering Vol. 24 (2004), p. 341-347 [10] S.
Gan: Journal of Materials Chemistry Vol. 9 (1999) p. 1635-1639 [12] I.
Gómez: Journal of Materials Science: Materials in Medicine Vol. 20 (2009), p. 2249-2257 [17] K.
Kumta: Materials Science and Engineering Vol. 27 (2007), p. 377-381
Shinomiya Materials Science and Engineering Vol. 24 (2004), p. 341-347 [10] S.
Gan: Journal of Materials Chemistry Vol. 9 (1999) p. 1635-1639 [12] I.
Gómez: Journal of Materials Science: Materials in Medicine Vol. 20 (2009), p. 2249-2257 [17] K.
Kumta: Materials Science and Engineering Vol. 27 (2007), p. 377-381
Online since: October 2015
Authors: Hong Shui Wang, Hai Long Liu, Chun Yong Liang, Bao Fa Li, Bao E Li, Chang Yi Li, Shi Min Liu, Chuang Huang
Pham, Investigation of Bacterial Attachment on Hydroxyapatite-Coated Titanium and Tantalum, International Journal of Surface Science and Engineering, 8 (2014) 255-263
Soballe, The Effect on Bone Growth Enhancement of Implant Coatings with Hydroxyapatite and Collagen Deposited Electrochemically and by Plasma Spray, Journal of Biomedical Materials Research Part A, 9999A (2009)
Waterfield, Effect of Titanium Surface Topography on Macrophage Activation and Secretion of Proinflammatory Cytokines and Chemokines, Journal of Biomedical Materials Research, 70A (2004) 194-205
Li Bioactivities of a Ti Surface Ablated with a Femtosecond Laser through Sbf, Biomedical Materials, 5 (2010) 054115
Chen, Nanocrystalline materials and coatings, Materials Science and Engineering: R: Reports, 45 (2004) 1-88
Soballe, The Effect on Bone Growth Enhancement of Implant Coatings with Hydroxyapatite and Collagen Deposited Electrochemically and by Plasma Spray, Journal of Biomedical Materials Research Part A, 9999A (2009)
Waterfield, Effect of Titanium Surface Topography on Macrophage Activation and Secretion of Proinflammatory Cytokines and Chemokines, Journal of Biomedical Materials Research, 70A (2004) 194-205
Li Bioactivities of a Ti Surface Ablated with a Femtosecond Laser through Sbf, Biomedical Materials, 5 (2010) 054115
Chen, Nanocrystalline materials and coatings, Materials Science and Engineering: R: Reports, 45 (2004) 1-88
Online since: March 2010
Authors: Li Zhang, Xian Zhang, Guo Da Chen, Ming Sheng Jin, Qiao Ling Yuan, Shi Ming Ji
Khatri: Journal of Materials Processing Technology, Vol. 190
(2007), p. 282-290
[3] T.
Kawashima: Journal of Materials Processing Technology, Vols. 143-144 (2003), p. 682-686 [5] J.
Choi: Journal of Material Processing Technology, Vol. 53 (1995), p. 630-642 [6] J.
Raghuram: Journal of Materials Processing Technology, Vol. 149 (2004), p. 22-29 [12] D.K.
Yuan: Key Engineering Materials, Vols. 304-305 (2006), p. 113-117 [18] S.M.
Kawashima: Journal of Materials Processing Technology, Vols. 143-144 (2003), p. 682-686 [5] J.
Choi: Journal of Material Processing Technology, Vol. 53 (1995), p. 630-642 [6] J.
Raghuram: Journal of Materials Processing Technology, Vol. 149 (2004), p. 22-29 [12] D.K.
Yuan: Key Engineering Materials, Vols. 304-305 (2006), p. 113-117 [18] S.M.
Online since: October 2010
Authors: Wei Min Gan, Zhang Guo Li, Xin Huang
References
[1] D.D.L Chung: Self-monitoring structural materials.
Materials Science and Engineering, Vol. 22 (1998), p. 57-58
Journal of Materials Science, Vol. 33 (1998), p. 3875-3884
Monteiro: Concrete: Microstructure, Properties, and Materials.
Journal of building materials.
Materials Science and Engineering, Vol. 22 (1998), p. 57-58
Journal of Materials Science, Vol. 33 (1998), p. 3875-3884
Monteiro: Concrete: Microstructure, Properties, and Materials.
Journal of building materials.
Online since: March 2022
Authors: Mohammad Ali Zazouli, Laleh Kalankesh
Journal of Materials Science: Materials in Electronics, 2019. 30: p. 10994-11004
Journal of Materials Chemistry A, 2018. 6(28): p. 13509-13537
Journal of hazardous materials, 2009. 170(2-3): p. 560-569
Advances in Materials Science and Engineering, 2015. 2015
Indian Journal of Materials Science, 2015. 2015
Journal of Materials Chemistry A, 2018. 6(28): p. 13509-13537
Journal of hazardous materials, 2009. 170(2-3): p. 560-569
Advances in Materials Science and Engineering, 2015. 2015
Indian Journal of Materials Science, 2015. 2015
Online since: July 2012
Authors: Liang Wu Bi, Zhen Dong Zhao, Lu Lu Han, Ya Li Xing
Previous research has reported that the better way to emulsify squalene is to use multicomponent shell materials.
Gelatin and arabic gum were chosen as shell materials because of their excellent emulsifying properties.
Spray drying has some drawbacks, e.g., high drying temperature and the wall materials should be highly soluble in water[9, 10].
Materials and methods Materials Squalene of 99.0 % purity, methanol was HPLC grade, gelatin and arabic gum analytical grade, n-hexane analytical grade, maltodextrin and sucrose ester were food grade.
(a) 28 kHz (b) 45 kHz (c) 100 kHz Fig.4 Metallographic microscopes of the emulsion at different frequency The reasonable ratio of shell materials Multicomponent shell materials including gelatin, arabic gum, maltodextrin and sucrose ester were chosen[8].
Gelatin and arabic gum were chosen as shell materials because of their excellent emulsifying properties.
Spray drying has some drawbacks, e.g., high drying temperature and the wall materials should be highly soluble in water[9, 10].
Materials and methods Materials Squalene of 99.0 % purity, methanol was HPLC grade, gelatin and arabic gum analytical grade, n-hexane analytical grade, maltodextrin and sucrose ester were food grade.
(a) 28 kHz (b) 45 kHz (c) 100 kHz Fig.4 Metallographic microscopes of the emulsion at different frequency The reasonable ratio of shell materials Multicomponent shell materials including gelatin, arabic gum, maltodextrin and sucrose ester were chosen[8].
Online since: March 2014
Authors: Xiao Min Tang, Yan Jie Song, Xin Deng, Jian Fu, Lin Hou
Study on Rock Conductive Law of Sandy Conglomerate Reservoir Based on Properties of Construction Materials
XiaoMin Tang 1, a, YanJie Song1, Jian Fu1, Lin Hou1, Xin Deng 1
1 Northeast Petroleum University, Daqing, Heilongjiang, China, 163318;
atxmdqpi@163.com
Keywords: Sandy conglomerate reservoir, ultra-low porosity and permeability reservoirs, full diameter core experiment, improved Archie formula, resistivity model
Abstract.
Acknowledgments This work is supported by the Natural Science Foundation of China (No. 41274110).
Journal of jilin university(earth science edition) Vol.33 (2003), p. 490 [2] Wang Zhuwen, Liu Jinghua, Xu Yanqing.
Journal of jilin university(earth science edition) Vol.33 (2003), p. 485 [3] Gao Boyu, Peng Shimi, Liu Hongqi.
Journal of northeast petroleum university Vol.37 (2013), p. 47
Acknowledgments This work is supported by the Natural Science Foundation of China (No. 41274110).
Journal of jilin university(earth science edition) Vol.33 (2003), p. 490 [2] Wang Zhuwen, Liu Jinghua, Xu Yanqing.
Journal of jilin university(earth science edition) Vol.33 (2003), p. 485 [3] Gao Boyu, Peng Shimi, Liu Hongqi.
Journal of northeast petroleum university Vol.37 (2013), p. 47
Online since: May 2014
Authors: Qian Qian Lin, Fan Bieke Wu, Zhen Guo Wang, Bin Liu, Rui Zhang
Objective: To test and contrastive analysis the crystal structure and mechanical characteristics of enamel and dentin of primary and permanent teeth by XRD and contact angle meter, provide information and experimental data for bionics and designs of dental materials.
Materials and Methods Teeth samples All the samples in this study were healthy primary and permanent teeth extracted for periodontal disease or orthodontic reasons with the donors from Lanzhou University Dental Hospital patients, Collected in Sept. 2011 - Sept. 2012.
Chinese Journal of Stomatology, 1998, 33(2):94-96 [3] Huang Yi.
Journal of Bethune medical university journal 1994; 20 (2): 194-195 [8] Bai,Ke; Zhang, Taihua;Yang,Zhiyu; Song,Fan;Yang, Xiaoda;Wang, Kui.
Chinese science bulletin 2007; 52 (8): 870-874 [9] Wang, Xiaobo;Yao,Yueling.
Materials and Methods Teeth samples All the samples in this study were healthy primary and permanent teeth extracted for periodontal disease or orthodontic reasons with the donors from Lanzhou University Dental Hospital patients, Collected in Sept. 2011 - Sept. 2012.
Chinese Journal of Stomatology, 1998, 33(2):94-96 [3] Huang Yi.
Journal of Bethune medical university journal 1994; 20 (2): 194-195 [8] Bai,Ke; Zhang, Taihua;Yang,Zhiyu; Song,Fan;Yang, Xiaoda;Wang, Kui.
Chinese science bulletin 2007; 52 (8): 870-874 [9] Wang, Xiaobo;Yao,Yueling.
Online since: March 2008
Authors: John P. Dismukes, Lawrence K. Miller, Andrew Solocha, John A. Bers
Wind Energy Electrical Power Generation Industry Life Cycle
Impact of Modern Materials Systems on Economic Viability
John P.
Materials and integrated materials systems featuring mechanical, structural, fluid dynamic, electrical, electronic, and telecommunications functionality developed and introduced over that period have contributed uniquely to current commercial viability of wind turbine electrical power generation.
Development of metallic, polymeric, ceramic and semiconductor materials and the engineering sciences related to materials strength / toughness / corrosion resistance, fluid dynamics, semiconductor devices, telecommunications, computers and the internet were necessary during the 20 th Century to make possible large scale wind turbine systems that can compete in energy delivery, control, and cost with hydroelectric, fossil fuel, and nuclear electrical generation systems.
Each of these obviously is made of materials systems of various functionality.
As summarized in Section IB, the role of the science, technology and manufacturing of diverse materials and materials systems were prerequisite to progressing wind energy electrical generation to stand-alone-cost commercial reality.
Materials and integrated materials systems featuring mechanical, structural, fluid dynamic, electrical, electronic, and telecommunications functionality developed and introduced over that period have contributed uniquely to current commercial viability of wind turbine electrical power generation.
Development of metallic, polymeric, ceramic and semiconductor materials and the engineering sciences related to materials strength / toughness / corrosion resistance, fluid dynamics, semiconductor devices, telecommunications, computers and the internet were necessary during the 20 th Century to make possible large scale wind turbine systems that can compete in energy delivery, control, and cost with hydroelectric, fossil fuel, and nuclear electrical generation systems.
Each of these obviously is made of materials systems of various functionality.
As summarized in Section IB, the role of the science, technology and manufacturing of diverse materials and materials systems were prerequisite to progressing wind energy electrical generation to stand-alone-cost commercial reality.
Online since: October 2013
Authors: Jian Ye, Wei Gao, Zhao Qiang Zeng, Chun Wu Liu
For 20 chrome molybdenum steel forged materials, E is elasticity modulus and E=206GPa. μ is Poisson's ratio and μ=0.30.
For powder hot forging materials: E is elasticity modulus and E=200GPa. μ is Poisson's ratio and μ=0.40. σb is tensile strength and σb=966MPa.
4.18 4.58 8 rounded transition of groove in big end hole 1.78 1.93 near rod body Conclusions (1) Both materials are safe according to the calculation of FEM.
The results show that rod made of powder forging materials is better than rod made of steel forging materials.
[3] Zude Li, Songlin Li, Moyue Zhao Mishing, in: submitted to Journal of Powder Metallurgy Materials Science and Engineering (No.10 of 2006), p.253-261 In Chinese [4] Xianyu Liu, in: submitted to Journal of Mechanical and Electrical Equipment (No.3 of 2005) , p.9-11 In Chinese
For powder hot forging materials: E is elasticity modulus and E=200GPa. μ is Poisson's ratio and μ=0.40. σb is tensile strength and σb=966MPa.
4.18 4.58 8 rounded transition of groove in big end hole 1.78 1.93 near rod body Conclusions (1) Both materials are safe according to the calculation of FEM.
The results show that rod made of powder forging materials is better than rod made of steel forging materials.
[3] Zude Li, Songlin Li, Moyue Zhao Mishing, in: submitted to Journal of Powder Metallurgy Materials Science and Engineering (No.10 of 2006), p.253-261 In Chinese [4] Xianyu Liu, in: submitted to Journal of Mechanical and Electrical Equipment (No.3 of 2005) , p.9-11 In Chinese