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Online since: April 2013
Authors: Khamlichi Abdellatif, Zineb Achegaf, Francisco Mata Cabrera
Walker: Life prediction and constitutive models for engine hot section, Anisotropic materials program.
Chaboche: Mechanics of solid materials, edited by Cambridge University Press, Cambridge, 1990
Skelton: Material Science Technology, Vol. 9 (1993), p.1001
Shang: Materials and Design, Vol. 31 (2010), p. 126
Ventura: Modeling and Simulation in Materials Science and Engineering, Vol. 17 (2009), p. 1
Chaboche: Mechanics of solid materials, edited by Cambridge University Press, Cambridge, 1990
Skelton: Material Science Technology, Vol. 9 (1993), p.1001
Shang: Materials and Design, Vol. 31 (2010), p. 126
Ventura: Modeling and Simulation in Materials Science and Engineering, Vol. 17 (2009), p. 1
Online since: October 2015
Authors: Jie Gang Mou, Tian Xing Fan, Lan Fang Jiang, Deng Hao Wu, Shui Hua Zheng, Yun Qing Gu
Journal of Huazhong University of Science of Technology: Natural Science Edition, 2014, 42(6), p 22-27
Science China: Technological Sciences, 2010, 11, p 2960-2965
Journal of Huazhong University of Science of Technology: Natural Science Edition, 2015, 43(1), p 16-20
Journal of Hazardous Materials, 2011, 197, p 169-175
Science China Technological Sciences, 2009, 52(2), p 273-284.
Science China: Technological Sciences, 2010, 11, p 2960-2965
Journal of Huazhong University of Science of Technology: Natural Science Edition, 2015, 43(1), p 16-20
Journal of Hazardous Materials, 2011, 197, p 169-175
Science China Technological Sciences, 2009, 52(2), p 273-284.
Online since: September 2013
Authors: Olurotimi A. Dahunsi, Temidayo Oluwagbenga Johnson, Olayinka O. Awopetu
Boyer: An Overview on the Use of Titanium in the Aerospace Industry, Materials Science and Engineering A.
Semiatin: Thermomechanical Procesing of Alpha Titanium Alloys – An Overview, Materials Science and Engineering.
Kander: Mechanical Properties of Ultra-Fine Grain Titanium, Journal of Achievement in Materials and Manufacturing Enginnering.
Gogia: Ti based Biomaterials, the Ultimate Choice for Orthopaedic Implants – A Review, Progress in Materials Science.
Ninnomi: Biocompatibility of Ti-Alloys for Long-Term Implantation, Journal of the Mechanical Behaviour of Biomedical Materials.
Semiatin: Thermomechanical Procesing of Alpha Titanium Alloys – An Overview, Materials Science and Engineering.
Kander: Mechanical Properties of Ultra-Fine Grain Titanium, Journal of Achievement in Materials and Manufacturing Enginnering.
Gogia: Ti based Biomaterials, the Ultimate Choice for Orthopaedic Implants – A Review, Progress in Materials Science.
Ninnomi: Biocompatibility of Ti-Alloys for Long-Term Implantation, Journal of the Mechanical Behaviour of Biomedical Materials.
Online since: January 2011
Authors: V. Swaminathan, M. Jayachandran, L.C. Nehru, C. Sanjeeviraja
Mulla, Journal of Materials Science Letters 19 (2000) 249– 252
[90] J.
Logana, Journal of Hazardous Materials 178 (2010) 29
XIAO, Materials Science-Poland, 26(3) (2008) 517
Li, Materials Science and Engineering A 426 (2006) 274
Morante, Materials Science and Engineering C 15 (2001) 203
Logana, Journal of Hazardous Materials 178 (2010) 29
XIAO, Materials Science-Poland, 26(3) (2008) 517
Li, Materials Science and Engineering A 426 (2006) 274
Morante, Materials Science and Engineering C 15 (2001) 203
Online since: July 2011
Authors: Krzysztof Werner, Stanisław Mroziński, Grzegorz Golański
Landgraf: Selecting materials to resist low cycle fatigue.
ASME, Journal of Basic Engineering, 1971, p.445
Lukaš: Materials Science and Engineering, Vol. 15, No. 213 1974, p. 231 [4] S.
Collins, Failure of Materials in Mechanical Design, Analysis, Prediction, Prevention.
ASME, Journal of Pressure Vessel Technology, Vol. 110, 1988, p. 35 [7] S.
ASME, Journal of Basic Engineering, 1971, p.445
Lukaš: Materials Science and Engineering, Vol. 15, No. 213 1974, p. 231 [4] S.
Collins, Failure of Materials in Mechanical Design, Analysis, Prediction, Prevention.
ASME, Journal of Pressure Vessel Technology, Vol. 110, 1988, p. 35 [7] S.
Online since: February 2011
Authors: Hong Ying Yu, Dong Bai Sun, An Qi Wu
Journal of Electroanalytical Chemistry: Vol. 582(2005), p.267
[2] A.
Computational Materials Science: Vol. 41(2008), p.255 [9] R.Pidaparti, M.
International Journal of Artificial Intelligence Tools Vol.14 (2005), p.361 [10] Q.
Materials Science and Engineering.
A, Structural Materials: Vol. 369(2004), p.284
Computational Materials Science: Vol. 41(2008), p.255 [9] R.Pidaparti, M.
International Journal of Artificial Intelligence Tools Vol.14 (2005), p.361 [10] Q.
Materials Science and Engineering.
A, Structural Materials: Vol. 369(2004), p.284
Online since: November 2012
Authors: Jun Feng Guan, Wei Feng Bai, Ying Cui, Qian Wang, Jian Wei Zhang
The damage and failure mechanism of quasi-brittle materials is the most fundamental research topic in Damage Mechanics.
Introduction The quasi-brittle materials such as concrete, rock and some ceramics are heterogeneous aggregate materials in meso-scale which are weakened by countless randomly distributed microcracks of irregular shapes and random in size and orientation in the microstructure and exhibit non-linear constitutive behavior on macro scale under exoteric loads [1-2].
However, there is a great gap between theoretical and practical damage processes, As Bazant [3] commented, PBS represents an unacceptable model for a material that is brittle on a large scale and it is not suitable for describing damage mechanisms of real materials.
Hu, Study on physical model of complete failure process of quasi-brittle materials in tension, Chinese Journal of Rock Mechanics and Engineering, 26 (2007) 670-681
Fan, The statistical damage model for quasi-brittle materials in uniaxial tension, Journal of Central South University of Technology, 16 (2009) 669-676
Introduction The quasi-brittle materials such as concrete, rock and some ceramics are heterogeneous aggregate materials in meso-scale which are weakened by countless randomly distributed microcracks of irregular shapes and random in size and orientation in the microstructure and exhibit non-linear constitutive behavior on macro scale under exoteric loads [1-2].
However, there is a great gap between theoretical and practical damage processes, As Bazant [3] commented, PBS represents an unacceptable model for a material that is brittle on a large scale and it is not suitable for describing damage mechanisms of real materials.
Hu, Study on physical model of complete failure process of quasi-brittle materials in tension, Chinese Journal of Rock Mechanics and Engineering, 26 (2007) 670-681
Fan, The statistical damage model for quasi-brittle materials in uniaxial tension, Journal of Central South University of Technology, 16 (2009) 669-676
Online since: January 2022
Authors: D.K. Sandi, Didier Fasquelle, Yofentina Iriani
Journal of Sol-Gel Science and Technology Vol. 86(1) (2018), p. 141
Materials (Basel) Vol. 13(2) (2020), p. 315
Iraqi Journal of Science Vol. 9 (2018), p. 97
Journal of Chemical Sciences Vol. 132(1) (2020), p. 129
Journal of Materials Research and Technology Vol. 9(5) (2020), p. 11439-11452
Materials (Basel) Vol. 13(2) (2020), p. 315
Iraqi Journal of Science Vol. 9 (2018), p. 97
Journal of Chemical Sciences Vol. 132(1) (2020), p. 129
Journal of Materials Research and Technology Vol. 9(5) (2020), p. 11439-11452
Online since: August 2019
Authors: Anil Kumar Bodukuri, Kesha Eswaraiah, V. Pradeep
Explore for new, high strength to weight ratio materials with better strength and toughness has guided to the improvement of a new age group of materials, while their properties may generate key challenges in machining operations.
Material that can be Machined All conducting metals and alloys Limitations Non conducting materials can’t be machined.
References [1] Che Chung Wang, Biing Hwa Yan, Blind-hole drilling of Al2O3/6061Al composite using rotary electro-discharge machining, Journal of Materials Processing Technology 102 (2000) 90-102
[2] S.Sivasankar, R.Jeyapaul, Performance study of tool materials and optimization of process parameters during EDM on zrb2-sic composite through particle swarm optimization algorithm, International Journal of Engineering Science and Technology, Vol. 5 No.01 January 2013
[3] Balbir Singh, Jatinder Kumar, Sudhir Kumar, Influences of Process Parameters on MRR Improvement in Simple and Powder Mixed EDM of AA6061/10%SiC Composite, Journal of Materials and Manufacturing Processes, December 2014, 303-312
Material that can be Machined All conducting metals and alloys Limitations Non conducting materials can’t be machined.
References [1] Che Chung Wang, Biing Hwa Yan, Blind-hole drilling of Al2O3/6061Al composite using rotary electro-discharge machining, Journal of Materials Processing Technology 102 (2000) 90-102
[2] S.Sivasankar, R.Jeyapaul, Performance study of tool materials and optimization of process parameters during EDM on zrb2-sic composite through particle swarm optimization algorithm, International Journal of Engineering Science and Technology, Vol. 5 No.01 January 2013
[3] Balbir Singh, Jatinder Kumar, Sudhir Kumar, Influences of Process Parameters on MRR Improvement in Simple and Powder Mixed EDM of AA6061/10%SiC Composite, Journal of Materials and Manufacturing Processes, December 2014, 303-312
Online since: July 2015
Authors: Yan Xu, Jian Pin Zhou, Zheng Ying Wei, Li Yan Dang, Feng Lin Wu
Introduction
With the development of modern biomedical technology and materials science, artificial bone substitute materials are increasingly used in clinical practice.
The alternative materials of biological activity are composed by HAP and SA, which are the preferred materials to form the composite bone scaffold.
[5] Xinwen Zhu, Dongliang Jiang preparation, Ting Hung Tan SiC Reticulated Porous Ceramics [J] Journal of Inorganic Materials, 2000, 5 (6): 1055 - 1060
Rare Metal Materials and Engineering, 2010,1 (39) :530-534
Mechanical Engineering Materials,2007,10:38-40
The alternative materials of biological activity are composed by HAP and SA, which are the preferred materials to form the composite bone scaffold.
[5] Xinwen Zhu, Dongliang Jiang preparation, Ting Hung Tan SiC Reticulated Porous Ceramics [J] Journal of Inorganic Materials, 2000, 5 (6): 1055 - 1060
Rare Metal Materials and Engineering, 2010,1 (39) :530-534
Mechanical Engineering Materials,2007,10:38-40