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Online since: December 2011
Authors: Anna Boczkowska, Grzegorz Slawinski, Danuta Miedzińska, Tadeusz Niezgoda
Sylvester Kaliskiego 2, 00-908 Warsaw 49, Poland
2Warsaw University of Technology, Faculty of Materials Science and Engineering, Woloska 141, 02-507 Warsaw, Poland
admiedzinska@wat.edu.pl (corresponding author), bgslawinski@wat.edu.pl, ctniezgoda@wat.edu.pl, dabocz@meil.pw.edu.pl
Keywords: Numerical modeling, microstructure, magnetorheological elastomer, smart materials, magnetic field.
This is achieved via adding the micro-sized magnetisable particles into the elastomers or rubber-like materials [1].
Awietjan, Urethane magnetorheological elastomers microstructure and properties, III ECCOMAS conference on Smart Structures and Materials, Gdansk (2007)
Munoz, A model of the behavior of magnetorheological materials, Smart Mater.
Munoz, A model of the behaviour of magnetorheological materials, Smart Mater.
This is achieved via adding the micro-sized magnetisable particles into the elastomers or rubber-like materials [1].
Awietjan, Urethane magnetorheological elastomers microstructure and properties, III ECCOMAS conference on Smart Structures and Materials, Gdansk (2007)
Munoz, A model of the behavior of magnetorheological materials, Smart Mater.
Munoz, A model of the behaviour of magnetorheological materials, Smart Mater.
Online since: November 2005
Authors: Francisco Rolando Valenzuela-Díaz, Carolina A. Pinto, P. Souza Santos, Shirley Cosin
ABSTRACT - Carbon/mineral complexes are materials with surfaces covered partially or totally
by carbon materials contains.
Ceramic properties These tests were performed only with materials D, E and F.
The other materials either crumbled or had a high mass loss.
Materials Chemistry and Physics, 34(2), 123-141 (1993). 2) Leboda, R.; Charmas, B.
Surface properties of mesoporous carbon-silica gel adsorbents, Journal of Colloid and Science Interface.223, 112-125 (2000). 4) Santos, P.S. - Science and Technology of Clays, 2 nd ed., Edgard Blücher, São Paulo, 1989 (vol1) and 1992 (vol. 2 and 3). 5) Cosin, S.
Ceramic properties These tests were performed only with materials D, E and F.
The other materials either crumbled or had a high mass loss.
Materials Chemistry and Physics, 34(2), 123-141 (1993). 2) Leboda, R.; Charmas, B.
Surface properties of mesoporous carbon-silica gel adsorbents, Journal of Colloid and Science Interface.223, 112-125 (2000). 4) Santos, P.S. - Science and Technology of Clays, 2 nd ed., Edgard Blücher, São Paulo, 1989 (vol1) and 1992 (vol. 2 and 3). 5) Cosin, S.
Online since: July 2014
Authors: Min Li Zheng, Wei Zhang, Zhao Xing Zhang, Shu Qi Wang, Xiao Liang Cheng
Verified by a large number of experiments of different workpiece materials, the residual stress predicted by models had a good agreement with the measured value [5].
Cutting Science and Technology Vol. 14(2) (2010), p. 244–257
Journal of Materials Processing Technology Vol. 209(9) (2009), 4515-4520
Materials and design Vol. 29(4)(2008), p. 873-883
CIRP Journal of Manufacturing Science Technology Vol. 4(1) (2011), p. 80-89
Cutting Science and Technology Vol. 14(2) (2010), p. 244–257
Journal of Materials Processing Technology Vol. 209(9) (2009), 4515-4520
Materials and design Vol. 29(4)(2008), p. 873-883
CIRP Journal of Manufacturing Science Technology Vol. 4(1) (2011), p. 80-89
Online since: May 2022
Authors: Vincenzo M. Sglavo, Farid Salari, Paolo Bosetti
Experimental Designs, Materials, and Methods
Materials.
Cavallini, Influence of curing temperature on the evolution of magnesium oxychloride cement, Journal of Materials Science. 46 (2011) 6726–6733
Kitchens, Kinetic study of the magnesium oxychloride cement cure reaction., Journal of Materials Science. 52 (2017)
Chmielus, Binder jet 3D printing—process parameters, materials, properties, modeling, and challenges, Progress in Materials Science. 119 (2021) 100707
Litster, Modeling the granule formation mechanism from single drop impact on a powder bed, Journal of Colloid and Interface Science. 393 (2013) 369–376
Cavallini, Influence of curing temperature on the evolution of magnesium oxychloride cement, Journal of Materials Science. 46 (2011) 6726–6733
Kitchens, Kinetic study of the magnesium oxychloride cement cure reaction., Journal of Materials Science. 52 (2017)
Chmielus, Binder jet 3D printing—process parameters, materials, properties, modeling, and challenges, Progress in Materials Science. 119 (2021) 100707
Litster, Modeling the granule formation mechanism from single drop impact on a powder bed, Journal of Colloid and Interface Science. 393 (2013) 369–376
Online since: October 2013
Authors: Hua Yan Chen, Xiang Guo Zeng, Yu Quan Yuan, Yan Fei Hu
Introduction
The micro-defects of materials,including voids, inclusions, and micro-cracks,will affect the mechanical properties of materials significantly.
References [1] K.Nishimura, N.Miyazaki, Molecular dynamics simulation of crack growth under cyclic loading, Computational Materials Science, 31 (2004) 269-278
Computational Materials Science, 2007, 40: 130–139
[13] K.J.Zhao, C.Q.Chen, Y.P.Shen, T.J.Lu, Molecular dynamics study on the nano-void growth in face-centered cubic single crystal copper, Computational Materials Science, 46 (2009) 749-754
[17] L.Yuan, D.B.Shan, B.Guo, Molecular dynamics simulation of tensile deformation of nano-single crystal aluminum, Journal of Materials Processing Technology, 184 (2007) 1–5
References [1] K.Nishimura, N.Miyazaki, Molecular dynamics simulation of crack growth under cyclic loading, Computational Materials Science, 31 (2004) 269-278
Computational Materials Science, 2007, 40: 130–139
[13] K.J.Zhao, C.Q.Chen, Y.P.Shen, T.J.Lu, Molecular dynamics study on the nano-void growth in face-centered cubic single crystal copper, Computational Materials Science, 46 (2009) 749-754
[17] L.Yuan, D.B.Shan, B.Guo, Molecular dynamics simulation of tensile deformation of nano-single crystal aluminum, Journal of Materials Processing Technology, 184 (2007) 1–5
Online since: August 2021
Authors: Elena P. Farafontova, Irina A. Pavlova, Valeriya È. Shvarczkopf
The ways of utilization of by-product are follows: as a filler for the silicate production; for polymer-cement, water-dispersion and oil paints; as a filler for the production of roofing materials, bituminous roofing mastics based on organic binders; raw materials for the production of foam glass materials and products.
The DSC curve is characteristic of glassy materials.
Preda, Cordierite-mullite porcelain stoneware, Romanian Journal of Materials. 42 (2012) 276-282
Farafontova, Effect of chemical composition of glassy phase of porcelain stoneware on product brittleness, Materials Science Forum. 989 (2020) 254-259
[24] GOST 2211-65 (ISO 5018-83) Refractories and Refractory Raw Materials.
The DSC curve is characteristic of glassy materials.
Preda, Cordierite-mullite porcelain stoneware, Romanian Journal of Materials. 42 (2012) 276-282
Farafontova, Effect of chemical composition of glassy phase of porcelain stoneware on product brittleness, Materials Science Forum. 989 (2020) 254-259
[24] GOST 2211-65 (ISO 5018-83) Refractories and Refractory Raw Materials.
Online since: September 2013
Authors: Hong Mei Cheng, Chuan Zhen Huang
The model was extended by Fang [4] and applied for simulating sintering process of two-phase ceramic materials.
These fabrication conditions will be used in sintering experiment of nanocomposite ceramic tool materials in order to compare with the simulation results.
The microstructure of nanocomposite ceramic tool materials at different sintering pressure is shown in Fig. 1.
Microstructure of nanocomposite ceramic tool materials Fig. 2 is the fracture surface of A12O3/nano-SiC nanocomposite ceramic tool materials, which is fabricated at 1600℃, sintering pressure of 0Mpa, 20MPa and 32MPa, respectively, grain size of SiC is 60nm.
Journal of Physics D: Applied Physics.
These fabrication conditions will be used in sintering experiment of nanocomposite ceramic tool materials in order to compare with the simulation results.
The microstructure of nanocomposite ceramic tool materials at different sintering pressure is shown in Fig. 1.
Microstructure of nanocomposite ceramic tool materials Fig. 2 is the fracture surface of A12O3/nano-SiC nanocomposite ceramic tool materials, which is fabricated at 1600℃, sintering pressure of 0Mpa, 20MPa and 32MPa, respectively, grain size of SiC is 60nm.
Journal of Physics D: Applied Physics.
Online since: January 2009
Authors: Y. Watanabe, Hitoshi Ohmori, T. Mishima, H. Kasuga
Mishima1, d
1
Graduate School of Science and Engineering Saitama University, Saitama, Japan
2
Materials Fabrication Laboratory, RIKEN, Saitama, Japan
3
RILAC Team, RIKEN, Saitama, Japan
a
kasuga@me.ics.saitama-u.ac.jp; bohmori@mfl.ne.jp; cwatanabe@nano.gr.jp;
d
takemi@mail.saitama-u.ac.jp
Keywords: Dental ceramics, Hard and brittle material, Surface characteristics, ELID-Grinding
Abstract.
Progress of new dental materials such as biocompatible metal, ceramics is being accelerated because of aging society and sophistication of medical treatment.
So, development of new dental materials such as biocompatible metal, ceramics is being accelerated because those materials are physically stable and hardly have harmful effect to human body.
In the case of materials for the dental implant treatment, fixtures are made of a biocompatible metal such as titanium, titanium alloy.
On the other hand, the coping made of dental ceramics does not cause metal allergy and has better translucency, but some ceramic materials have lower strength than biocompatible metal.
Progress of new dental materials such as biocompatible metal, ceramics is being accelerated because of aging society and sophistication of medical treatment.
So, development of new dental materials such as biocompatible metal, ceramics is being accelerated because those materials are physically stable and hardly have harmful effect to human body.
In the case of materials for the dental implant treatment, fixtures are made of a biocompatible metal such as titanium, titanium alloy.
On the other hand, the coping made of dental ceramics does not cause metal allergy and has better translucency, but some ceramic materials have lower strength than biocompatible metal.
Online since: November 2010
Authors: Li Li Zhang, Yong Tan, Jie Sun
Maaz, W.Khalid and A.Mumtaz: Physica E, 41 (2009), p. 593
[2] A L Quinelato, E Longo and E R Leite: Journal of Materials Science, 36(2001), p. 3825
[3] Zhitao Chen and Lian Gao: Materials Science and Engineering B, 141 (2007), p. 82
[4] Yuan Zhihao and Zhang Lide: Materials Research Bulletin, 33(1998), p. 1587
[5] Dong-Hwang Chen and Xin-Rong He: Materials Research Bulletin, 36 (2001), p. 1369
[6] Qi Chen, Adam J.
John Zhang: Journal of Magnetism and Magnetic Materials, 194 (1999), p. 1 [7] Sung-Soo Kima, Seon-Tae Kima and Joon-Mo Ahnb: Journal of Magnetism and Magnetic Materials, 271 (2004), p. 39 [8] S.
Macedo: Journal of Magnetism and Magnetic Materials, 192 (1999), p. 277 [11] T.
Serna: Materials Letters, 43(20000, p. 97 [12] Y.
Yin: Journal of Alloys and Compounds, 308 (2000), p. 290 [13] Zhong Weilie: Ferroelectrics Physics (Science Press, China 2000).
John Zhang: Journal of Magnetism and Magnetic Materials, 194 (1999), p. 1 [7] Sung-Soo Kima, Seon-Tae Kima and Joon-Mo Ahnb: Journal of Magnetism and Magnetic Materials, 271 (2004), p. 39 [8] S.
Macedo: Journal of Magnetism and Magnetic Materials, 192 (1999), p. 277 [11] T.
Serna: Materials Letters, 43(20000, p. 97 [12] Y.
Yin: Journal of Alloys and Compounds, 308 (2000), p. 290 [13] Zhong Weilie: Ferroelectrics Physics (Science Press, China 2000).
Online since: October 2015
Authors: Angsumalin Senjuntichai, Somkiat Tangjitsitcharoen, Thanathip Jatinandana
Hayhurst: Development of Models for Tool Wear Force Relationships in Metal Cutting, International Journal of Mechanical Science Vol. 33 (1991), p. 125-138
[4] M.A.
El-Hossainy: Investigating the Tool Life, Cutting Force Components, and Surface Roughness of AISI 302 Stainless Steel Material Under Oblique Machining, Materials and Manufacturing Processes Vol. 23 (2008), p. 427-438 [13] K.J.
El-Zahry: Monitoring of tool wear and surface roughness in endmilling for intelligent machining, International Journal of the Physical Sciences Vol. 6 (2010), p. 2380-2392 [15] B.
Senjuntichai: Intelligent Monitoring and Prediction of Surface Roughness in Ball End Milling Process, Applied Mechanics and Materials.
Ratanakuakangwan: Monitoring and Prediction of Surface Roughness in Ball End Milling with Air Blow Application, Advanced Materials Research.
El-Hossainy: Investigating the Tool Life, Cutting Force Components, and Surface Roughness of AISI 302 Stainless Steel Material Under Oblique Machining, Materials and Manufacturing Processes Vol. 23 (2008), p. 427-438 [13] K.J.
El-Zahry: Monitoring of tool wear and surface roughness in endmilling for intelligent machining, International Journal of the Physical Sciences Vol. 6 (2010), p. 2380-2392 [15] B.
Senjuntichai: Intelligent Monitoring and Prediction of Surface Roughness in Ball End Milling Process, Applied Mechanics and Materials.
Ratanakuakangwan: Monitoring and Prediction of Surface Roughness in Ball End Milling with Air Blow Application, Advanced Materials Research.