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Online since: October 2011
Authors: Ze Li, Li Xiang Zhang
Introduction
The gravity dam is generally built by the mass concrete material.
Acknowledgements The research of this paper has received financial supports from National Natural Science Foundation of China (grant number: 50839003, 51009074) and Yunnan Province Application Basic Research Fund (grant number: 2008ZC028M).
[5] Ghrib F, Tinawi R: Journal of Engineering Mechanics, Vol. 121-4 (1995), p. 513-527 [6] Lubliner, J., J.
Oñate: International Journal of Solids and Structures, Vol. 25-3 (1989), p. 229-326 [7] Lee, J., G.
Fenves: Journal of Engineering Mechanics, Vol. 124-8 (1998), p. 892-900 [8] Westergaard H M: Transactions of the American Society of Civil Engineers, Vol. 98 (1933), p. 418-433
Acknowledgements The research of this paper has received financial supports from National Natural Science Foundation of China (grant number: 50839003, 51009074) and Yunnan Province Application Basic Research Fund (grant number: 2008ZC028M).
[5] Ghrib F, Tinawi R: Journal of Engineering Mechanics, Vol. 121-4 (1995), p. 513-527 [6] Lubliner, J., J.
Oñate: International Journal of Solids and Structures, Vol. 25-3 (1989), p. 229-326 [7] Lee, J., G.
Fenves: Journal of Engineering Mechanics, Vol. 124-8 (1998), p. 892-900 [8] Westergaard H M: Transactions of the American Society of Civil Engineers, Vol. 98 (1933), p. 418-433
Online since: March 2015
Authors: Mao Fang Huang, Hui Huang, Y.F. Fu, J. Gong, D.M. Zhu, Y.J. Liu
Food Science and Technology. 39(4) (2014) 106-110
The Journal of Supercritical Fluids.48(3) (2009) 203-210
Journal of Hefei University of Technology. 36(4) (2013) 401-405
Journal of Materials Processing Technology. 110(5) (2001) 19-27
Journal of Machine Design. 30(11) (2013) 13-16.
The Journal of Supercritical Fluids.48(3) (2009) 203-210
Journal of Hefei University of Technology. 36(4) (2013) 401-405
Journal of Materials Processing Technology. 110(5) (2001) 19-27
Journal of Machine Design. 30(11) (2013) 13-16.
Online since: October 2012
Authors: Song Gu, Chao Wang, Lu Li, Kai Lin, Yu Ping Gan
China's building materials industry defined specifically in the "Eleventh Five-Year Plan" about the key point on the development of new wall materials and structural adjustment:“Developing new wall materials to promote the economy, resources, and environmental development [4]”.
Standing on view of the demand of market, according to statistics, Chinese actual output of the concrete block only accounts for 1.94% of the wall materials.
It is predicted that: The demand of new wall material will reaches 23.25 million cubic meters in 2013, demand for concrete block will account for 10 percent of new wall materials.
There is a small amount of industrial waste residue mixed in the raw materials.
Acknowledgements This work was financially supported by National High Technology Research and Development Program (2009AA032304) References [1] Taiping Guo, Huiqiang Li: Science and Technology of Overseas Building Materials, Vol.06 (2003), P.64-65 (In Chinese) [2] Xianliang Wang: Journal of Hubei Radio & Television University, Vol.28 (08) (2008), P.110-111 (In Chinese) [3] Ming Yu; Hangzhou Science and Technology, Vol.03 (2005), P.29 (In Chinese) [4] Ying Wang, Hui Zhang: Hei Longjiang Science and Technology Information, Vol.34 (2009), P. 351 (In Chinese) [5] Ting Du, Taiping Guo, Huaili Lin: Concrete, Vol.05 (2006), P.7-9 (In Chinese)
Standing on view of the demand of market, according to statistics, Chinese actual output of the concrete block only accounts for 1.94% of the wall materials.
It is predicted that: The demand of new wall material will reaches 23.25 million cubic meters in 2013, demand for concrete block will account for 10 percent of new wall materials.
There is a small amount of industrial waste residue mixed in the raw materials.
Acknowledgements This work was financially supported by National High Technology Research and Development Program (2009AA032304) References [1] Taiping Guo, Huiqiang Li: Science and Technology of Overseas Building Materials, Vol.06 (2003), P.64-65 (In Chinese) [2] Xianliang Wang: Journal of Hubei Radio & Television University, Vol.28 (08) (2008), P.110-111 (In Chinese) [3] Ming Yu; Hangzhou Science and Technology, Vol.03 (2005), P.29 (In Chinese) [4] Ying Wang, Hui Zhang: Hei Longjiang Science and Technology Information, Vol.34 (2009), P. 351 (In Chinese) [5] Ting Du, Taiping Guo, Huaili Lin: Concrete, Vol.05 (2006), P.7-9 (In Chinese)
Online since: December 2023
Authors: Kei Ameyama, Mie Kawabata, Tomoko Kuno, Akiyoshi Koiso, Hiroshi Fujiwara
High wear resistance, high toughness, and high temperature resistance are important properties for mold materials.
The mold materials must have excellent wear resistance and high toughness in order to achieve a long life and a high precision.
Mondal, Wear Behavior of Harmonic Structured 304L Stainless Steel, Journal of Materials Engineering and Performance, Vol. 26, No.6(2017), 2608–2618
Ota, Harmonic Structure Design for High Strength and High Ductility Materials Production, Journal of the Japan Society of Powder and Powder Metallurgy, Vol. 64, No. 1(2017), 3-10
Masatomi, Bend Deformation and Fracture of WC-Co Alloys at Elevated Temperatures, Materials Transactions, Vol. 18, No.3(1977), 247-256.
The mold materials must have excellent wear resistance and high toughness in order to achieve a long life and a high precision.
Mondal, Wear Behavior of Harmonic Structured 304L Stainless Steel, Journal of Materials Engineering and Performance, Vol. 26, No.6(2017), 2608–2618
Ota, Harmonic Structure Design for High Strength and High Ductility Materials Production, Journal of the Japan Society of Powder and Powder Metallurgy, Vol. 64, No. 1(2017), 3-10
Masatomi, Bend Deformation and Fracture of WC-Co Alloys at Elevated Temperatures, Materials Transactions, Vol. 18, No.3(1977), 247-256.
Online since: June 2012
Authors: Su Fen Wang, Zhi Jie Li, Yan Peng, Yun Fei Liu
Transactions of Materials and Heat Treatment, (2007),p.130-133.
Transactions of Materials and Heat Treatment, Vol. 06(2011), p.109-113.
In Chinese [3] Xiangdong Huo, Xinping Mao, Shengxia Lv, et al.Journal of University of Science and Technology Brijing, Vol. 08(2011),p.941-946.
Materials Science and Engineering: A.
Materials Science and Engineering: A.
Transactions of Materials and Heat Treatment, Vol. 06(2011), p.109-113.
In Chinese [3] Xiangdong Huo, Xinping Mao, Shengxia Lv, et al.Journal of University of Science and Technology Brijing, Vol. 08(2011),p.941-946.
Materials Science and Engineering: A.
Materials Science and Engineering: A.
Online since: June 2011
Authors: Xiao Ming Sui, Xi Liang Xu, Xiao Meng Zheng, Guang Zhi Xu, Qiang Wang
Preparation and Characterization of Carbon Fibre Reinforced Aluminium Matrix Composite
Xiaoming Sui, Xiliang Xu, Xiaomeng Zheng, Guangzhi Xu and Qiang Wang*
School of materials science and engineering, Jilin University, China
Keywords: Aluminium matrix composite, Carbon fibre, Preparation, Characterization.
Second, new concepts and advanced materials are needed to face the challenge of next century’s mass air transportation [1].
Experimental Raw materials.
Heinz, Recent development in aluminium alloys for aerospace applications, Materials Science and Engineering, A280 (2000) 102–107 [2] J.B.
Chand, Carbon fibers for composites, Journal of Materials Science 35 (2000) 1303–1313
Second, new concepts and advanced materials are needed to face the challenge of next century’s mass air transportation [1].
Experimental Raw materials.
Heinz, Recent development in aluminium alloys for aerospace applications, Materials Science and Engineering, A280 (2000) 102–107 [2] J.B.
Chand, Carbon fibers for composites, Journal of Materials Science 35 (2000) 1303–1313
Online since: December 2012
Preface
JBBTE is one of the few journals in the biomaterials and tissue engineering realm that publishes both
research papers and review papers, and this journal spans the diverse but closely interrelated fields
of Biomimetics, Biomaterials, and Tissue Engineering.
Ghezzo and Miao (Italy) present a detailed and comprehensive biomimetics review paper on biomimetically-inspired self-healing materials.
A broad range of self-healing materials are presented, with a focus on composites with matrices that can self-heal the cracks by repairing the broken molecular links upon external heating.
I am sure you will find this collection of cutting edge papers as interesting and thought-provoking as I have, and as always in JBBTE, you will see science and engineering bridging the three inter-related disciplines of Biomimetics, Biomaterials, and Tissue Engineering.
Ghezzo and Miao (Italy) present a detailed and comprehensive biomimetics review paper on biomimetically-inspired self-healing materials.
A broad range of self-healing materials are presented, with a focus on composites with matrices that can self-heal the cracks by repairing the broken molecular links upon external heating.
I am sure you will find this collection of cutting edge papers as interesting and thought-provoking as I have, and as always in JBBTE, you will see science and engineering bridging the three inter-related disciplines of Biomimetics, Biomaterials, and Tissue Engineering.
Online since: March 2013
Authors: Jing Wu Zheng, Liang Qiao, Jie Chen, Li Qiang Jiang
The pH Influence on the Preparation of Hollow Fe2O3 Spheres by Hydrothermal Method
QIAO liang1, a, CHEN jie1, b, JIANG li-qiang1, c, ZHENG jing-wu1, d*
1Collage of Chemical Engineering and Material Science, Zhejiang University of Technology, Hangzhou 310014, P.
In this paper Fe2O3 precursor coating on the surface of carbon balls was prepared by hydrothermal method using Fe(NO3)3·9H20 and glucose as the raw materials.
Fe2O3 is a n-type semiconductor materials with the gap E=2.2 eV at the room temperature.
Li and Enbo Wang: Journal of Crystal Growth.
PAN: Functional Materials Supplement, Vol. 10(2001), p. 1134.
In this paper Fe2O3 precursor coating on the surface of carbon balls was prepared by hydrothermal method using Fe(NO3)3·9H20 and glucose as the raw materials.
Fe2O3 is a n-type semiconductor materials with the gap E=2.2 eV at the room temperature.
Li and Enbo Wang: Journal of Crystal Growth.
PAN: Functional Materials Supplement, Vol. 10(2001), p. 1134.
Online since: October 2013
Authors: Xiao Tang
Experimental
2.1 Materials
All chemicals used are analytical grade and used as received.
Science 334 (2011) 629-633
Journal of Colloid and Interface Science 330 (2009) 386-391
Materials Chemistry and Physics 134 (2012) 170-176
Materials Chemistry and Physics 130 (2011) 843-846
Science 334 (2011) 629-633
Journal of Colloid and Interface Science 330 (2009) 386-391
Materials Chemistry and Physics 134 (2012) 170-176
Materials Chemistry and Physics 130 (2011) 843-846
Online since: August 2019
Authors: Ramez A. Al-Mansob, Mohd Raihan Taha, Jamal M.A. Alsharef, Panbarasi Govindasamy
Materials and Methods
2.1.
Materials The Carbon nanotube (CNT) supplied by France Company, Arkema Incorporation marketed under the trade name Graphistrength is used in this study.
Torkittikul, “Compressive strength and microstructure of carbon nanotubes–fly ash cement composites,” Materials Science and Engineering: A, vol. 527, no. 4-5, pp. 1063-1067, 2010. https://doi.org/10.1016/j.msea.2009.09.039 [16] L.
Sun, “Production of aqueous colloidal dispersions of carbon nanotubes,” Journal of Colloid and Interface Science, vol. 260, no. 1, pp. 89-94, 2003. https://doi.org/10.1016/S0021-9797(02)00176-5 [17] L.
Mohammad, “Optimization of nickel oxide nanoparticle synthesis through the sol–gel method using Box–Behnken design,” Materials & Design, vol. 86, pp. 948-956, 2015. https://doi.org/10.1016/j.matdes.2015.07.176 [26] M.
Materials The Carbon nanotube (CNT) supplied by France Company, Arkema Incorporation marketed under the trade name Graphistrength is used in this study.
Torkittikul, “Compressive strength and microstructure of carbon nanotubes–fly ash cement composites,” Materials Science and Engineering: A, vol. 527, no. 4-5, pp. 1063-1067, 2010. https://doi.org/10.1016/j.msea.2009.09.039 [16] L.
Sun, “Production of aqueous colloidal dispersions of carbon nanotubes,” Journal of Colloid and Interface Science, vol. 260, no. 1, pp. 89-94, 2003. https://doi.org/10.1016/S0021-9797(02)00176-5 [17] L.
Mohammad, “Optimization of nickel oxide nanoparticle synthesis through the sol–gel method using Box–Behnken design,” Materials & Design, vol. 86, pp. 948-956, 2015. https://doi.org/10.1016/j.matdes.2015.07.176 [26] M.