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Online since: January 2012
Authors: Jun Lin Tao, Yong Yao, Xiao Ling Liu, Qian Hui Ren, Yi Zeng
Parameters of constitutive model for all materials in the target shown in Table 2.
[7] Goble C F, Cohen M D: ACI Materials Journal .
[8] Gopalaratnam V S, Shah S P: ACI Materials Journal.
[9] Harsh S, Shen Z, Darwin D: ACI Materials Journal.
[10] Hsu T C, Slate F O: ACI Materials Journal.
[7] Goble C F, Cohen M D: ACI Materials Journal .
[8] Gopalaratnam V S, Shah S P: ACI Materials Journal.
[9] Harsh S, Shen Z, Darwin D: ACI Materials Journal.
[10] Hsu T C, Slate F O: ACI Materials Journal.
Online since: August 2011
Authors: Zhi Ming Yu, Jia Xiu Hu, Jian Zhao, Yun Song Niu
The Ni-based reticular MnOx catalytic materials with high porosity and high specific area were prepared by the electrodeposition method.
Pd plate and bulk manganese were choose as anode materials.
Results and discussion The XRD patterns of MnOx catalytic materials Fig.1.
Materials chemistry and Physics. 113 (2009) 650 [6] C.
Journal of Electroanal.
Pd plate and bulk manganese were choose as anode materials.
Results and discussion The XRD patterns of MnOx catalytic materials Fig.1.
Materials chemistry and Physics. 113 (2009) 650 [6] C.
Journal of Electroanal.
Online since: May 2020
Authors: S.M. Rakhimbaev, A.A. Logvinenko, M.I. Logvinenko
Ahmad, Production of High-Performance Silica Fume Concrete, American Journal of Applied Sciences. 14 (11) (2017) 1031-1038
Zajcevet, Effective Fine-Grained Concrete with High-Dispersed Additive Based on the Natural Mineral Wollastonite, Materials Science Forum. 945 (2019) 85-90
Nehdi, Effect of Natural Wollastonite Microfibers on Early-Age Behavior of UHPC, Journal of Materials in Civil Engineering. 24(7) (2012) 816-824
Kaftaeva, On the influence of the shape of a cement ring on its own deformations and stresses, Journal Building Materials. 9 (2009) 91-92
Materials Science Forum. 945 (2019) 771-775.
Zajcevet, Effective Fine-Grained Concrete with High-Dispersed Additive Based on the Natural Mineral Wollastonite, Materials Science Forum. 945 (2019) 85-90
Nehdi, Effect of Natural Wollastonite Microfibers on Early-Age Behavior of UHPC, Journal of Materials in Civil Engineering. 24(7) (2012) 816-824
Kaftaeva, On the influence of the shape of a cement ring on its own deformations and stresses, Journal Building Materials. 9 (2009) 91-92
Materials Science Forum. 945 (2019) 771-775.
Online since: February 2019
Authors: M.Y. Elistratkin, M.V. Absimetov, V.V. Voronov, E.S. Glagolev
Karakurt, Properties of the autoclaved aerated concrete produced from coal bottom ash, Journal of materials processing technology. 209.2 (2009) 767-773
[8] Wan-liang ZHOU, Jing-hua LONG, Bing-gen ZHAN, Further Study on Property of Fly Ash-Fluorogypsum-Cement Composite Binder, Journal of Building Materials. 2 (2008) 13-18
Levchenko, Green composites in architecture and building material science, Modern Applied Science Journal. 9.1 (2015) 45-50
Elistratkin, Anisotropy of materials properties of natural and man-triggered origin, Research Journal of Applied Sciences. 9.11 (2014) 816-819
Shapovalov, Steam curing characteristics of cellular concrete on the base of nanostructured binder, Journal of Fundamental and Applied Sciences. 8.38 (2016) 1480-1488
[8] Wan-liang ZHOU, Jing-hua LONG, Bing-gen ZHAN, Further Study on Property of Fly Ash-Fluorogypsum-Cement Composite Binder, Journal of Building Materials. 2 (2008) 13-18
Levchenko, Green composites in architecture and building material science, Modern Applied Science Journal. 9.1 (2015) 45-50
Elistratkin, Anisotropy of materials properties of natural and man-triggered origin, Research Journal of Applied Sciences. 9.11 (2014) 816-819
Shapovalov, Steam curing characteristics of cellular concrete on the base of nanostructured binder, Journal of Fundamental and Applied Sciences. 8.38 (2016) 1480-1488
Online since: March 2007
Authors: Viola L. Acoff, Ren Gang Zhang
Wagner: Materials Science and Engineering, R 22, (1998), p.187
Martin: Materials Science and Engineering A, Vol. 243 (1998), p. 25
Froes: Materials Science and Engineering, Vol. 98 (1988), p.257
Chaudhari: Materials Science Forum, Vol.426-432 (2003), p.1873
Chaturvedi: Materials Science and Engineering Vol.
Martin: Materials Science and Engineering A, Vol. 243 (1998), p. 25
Froes: Materials Science and Engineering, Vol. 98 (1988), p.257
Chaudhari: Materials Science Forum, Vol.426-432 (2003), p.1873
Chaturvedi: Materials Science and Engineering Vol.
Online since: June 2012
Authors: Bao Cai Xu, Liang Liu
Preparing and Characterization of Hollow Ceramic Microspheres
Liang Liua ,Baocai Xu
Institute of Advanced Materials, Mechanical Engineering College, Shijiazhuang 050003, China
a Llppmouse@163.com
Keywords: Hollow ceramic microspheres; Absorb material; Self-reactive flame spraying method; equips of collection
Abstract: The hollow microsphere is a kind of new materials .Its comprehensive performance is excellent and has a bright future.
Fig.1 SEM of the hollow ceramic microsphere Fig.2 XRD of the hollow ceramic microsphere As a bran-new microballoon materia, hollow microsphere can also be used for stealth materials.
Journal of Central South University of Technology. 4 (2011) 35-41
Journal of University of Science and Technology Beijing. 4(2004) 20-24
Journal of Central South University of Technology. 2(2004) 34-36
Fig.1 SEM of the hollow ceramic microsphere Fig.2 XRD of the hollow ceramic microsphere As a bran-new microballoon materia, hollow microsphere can also be used for stealth materials.
Journal of Central South University of Technology. 4 (2011) 35-41
Journal of University of Science and Technology Beijing. 4(2004) 20-24
Journal of Central South University of Technology. 2(2004) 34-36
Online since: January 2010
Authors: Serge Tcherniaeff, Franck Girot, Ivan Iordanoff
The first condition to respect is the choice of the materials "Real" and the "Model".
The law of flow"s material formulates that as for real materials, simulation materials behave the same when constraints overcome a certain threshold.
The materials used as follows: representing AA2024T3 is beige plasticine (modeling clay) and red plasticine for the copper sheet[9,10].
The final result will be the creation of a model of FSW for different materials with different kind of joining 5_References [1] NANDAN (R)-DEBROY (T)-BHADESHIA (H K D H) - Recent advances in Friction Stir Welding-Process,Weldment, Structure and properties - Progress in Materials Science 53 PP 980-1023 (2008) [2] BASTIER (A), Modélisation du soudage d'alliages d'aluminium par friction et malaxage, Thèse de doctorat de l'Ecole Polytechnique, décembre (2006) [3] GLUKHMAN (A.A.). - Introduction to the theory of similarity.
[6] LE FLOCH (A)-JACOMET (S)-MONTMITONNET (P) Simulation physique des procédés de mise en forme : Théorie et pratique Techniques de l'Ingénieur, traité Matériaux métalliques M3020 (1997) [7] BUFFA (G) HUA (J) SHIVPURI (R) FRATINI (L) - Design of the friction stir welding tool using the continuum based FEM model - Materials science & Engineering - MSA-19606; (2005) [8] DICKERSON (T) SHERCLIFF (H) SCHMIDT (H) - A weld marker technique for flow visualization in friction stir welding - 4 th International Symposium on Friction Stir Welding, ParkCity, Utah, USA (2003) [9] LIECHTY BC, WEBB BW - Flow field characterization of friction stir processing using a particle -grid method - Journal of materials processing technology 208 pp431-443 (2008) [10] LIECHTY BC, WEBB BW - the use of plasticine as an analog to explore material flow in friction stir welding - Journal of materials processing technology 184 pp240-250 (2007)
The law of flow"s material formulates that as for real materials, simulation materials behave the same when constraints overcome a certain threshold.
The materials used as follows: representing AA2024T3 is beige plasticine (modeling clay) and red plasticine for the copper sheet[9,10].
The final result will be the creation of a model of FSW for different materials with different kind of joining 5_References [1] NANDAN (R)-DEBROY (T)-BHADESHIA (H K D H) - Recent advances in Friction Stir Welding-Process,Weldment, Structure and properties - Progress in Materials Science 53 PP 980-1023 (2008) [2] BASTIER (A), Modélisation du soudage d'alliages d'aluminium par friction et malaxage, Thèse de doctorat de l'Ecole Polytechnique, décembre (2006) [3] GLUKHMAN (A.A.). - Introduction to the theory of similarity.
[6] LE FLOCH (A)-JACOMET (S)-MONTMITONNET (P) Simulation physique des procédés de mise en forme : Théorie et pratique Techniques de l'Ingénieur, traité Matériaux métalliques M3020 (1997) [7] BUFFA (G) HUA (J) SHIVPURI (R) FRATINI (L) - Design of the friction stir welding tool using the continuum based FEM model - Materials science & Engineering - MSA-19606; (2005) [8] DICKERSON (T) SHERCLIFF (H) SCHMIDT (H) - A weld marker technique for flow visualization in friction stir welding - 4 th International Symposium on Friction Stir Welding, ParkCity, Utah, USA (2003) [9] LIECHTY BC, WEBB BW - Flow field characterization of friction stir processing using a particle -grid method - Journal of materials processing technology 208 pp431-443 (2008) [10] LIECHTY BC, WEBB BW - the use of plasticine as an analog to explore material flow in friction stir welding - Journal of materials processing technology 184 pp240-250 (2007)
Online since: January 2012
Authors: Wang Ping Wu, Zhou Chen, Teng Zhou Xu, Jie Ming Zhou, Zhao Feng Chen, Xue Yu Cheng
Ultrafine Glass Fiber Core Material Produced by Wet method
Tengzhou Xu1,a, Zhaofeng Chen1,b, Jieming Zhou2,c, Xueyu Cheng2,d, Wangping Wu1,e, Zhou Chen1,f
1College of Material Science and technology, Nanjing University of Aeronautics and Astronautics, Nanjing 210016, P.R.
In general, the core materials have fibers, powders and foams [2].
Moreover, volume weight (about 150kg/m3) of the ultrafine glass fiber core materials is smaller than that of conventional insulation core materials, such as fumed silica, precipitated silica and so on.
Therefore, molecular collision doesn’t occur in the interior of core materials.
Lackey: Journal of Cold Regions Engineering, Vol. 22 (2008), p. 103 [2] J.
In general, the core materials have fibers, powders and foams [2].
Moreover, volume weight (about 150kg/m3) of the ultrafine glass fiber core materials is smaller than that of conventional insulation core materials, such as fumed silica, precipitated silica and so on.
Therefore, molecular collision doesn’t occur in the interior of core materials.
Lackey: Journal of Cold Regions Engineering, Vol. 22 (2008), p. 103 [2] J.
Online since: November 2010
Authors: Hong Lin, Xiao Chong Zhao, Yi Zhu Liu, Xin Li, Jian Bao Li
Minoura: Advanced Materials Vol. 12 (2000), p. 1214-1217
Minoura: Advanced Materials Vol. 15 (2003), p. 814-817
Spiccia: Journal of Sol-Gel Science and Technology Vol. 40 (2006), p. 45-54
Shin: Advanced Materials Vol. 17 (2005), p. 2349-2353
Frank: Chemistry of Materials Vol. 14 (2002), p. 1042-1047
Minoura: Advanced Materials Vol. 15 (2003), p. 814-817
Spiccia: Journal of Sol-Gel Science and Technology Vol. 40 (2006), p. 45-54
Shin: Advanced Materials Vol. 17 (2005), p. 2349-2353
Frank: Chemistry of Materials Vol. 14 (2002), p. 1042-1047
Online since: June 2008
Authors: Michael V. Swain, Wei Li, Qing Li, Daniel Lin
Abstract
Currently, titanium dominates the dental implant materials due to its strength and bio-inerrability.
New implant materials are proposed, the most promising new implant material is perhaps functionally graded material, for short FGM [2, 3].
Journal of Biomedical Materials Research Part B-Applied Biomaterials, 2005. 75B(1): p. 74-80. 3.
Composites Science and Technology, 2004. 64(6): p. 893-908. 4.
Journal of Biomedical Materials Research Part A, 2007. 80A(1): p. 146-158. 5.
New implant materials are proposed, the most promising new implant material is perhaps functionally graded material, for short FGM [2, 3].
Journal of Biomedical Materials Research Part B-Applied Biomaterials, 2005. 75B(1): p. 74-80. 3.
Composites Science and Technology, 2004. 64(6): p. 893-908. 4.
Journal of Biomedical Materials Research Part A, 2007. 80A(1): p. 146-158. 5.