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Online since: July 2010
Erb received his M.A.Sc. (1978) and Ph.D. (1980) in Materials Science from the
University of the Saarland (Germany).
He currently is Professor in the Department of Materials Science and Engineering at the University of Toronto.
Presently Advisor/Consultant in Materials Science.
He is currently working as an associate professor at School of Materials Science and Engineering, The University of New South Wales.
Presently, he is working as an Assistant Professor in Materials Research Centre, Indian Institute of Science, India.
He currently is Professor in the Department of Materials Science and Engineering at the University of Toronto.
Presently Advisor/Consultant in Materials Science.
He is currently working as an associate professor at School of Materials Science and Engineering, The University of New South Wales.
Presently, he is working as an Assistant Professor in Materials Research Centre, Indian Institute of Science, India.
Online since: December 2025
Authors: Ashok Kumar Palaniappan, V. Sivaprasad, A.R. Karthik Bharathi, R.M. Mukesh, S.P. Rajesh
Materials Research Bulletin 150: 111761
Materials Chemistry and Physics 275: 125283
Journal of Materials Engineering and Performance: 1–12
Journal of Materials Engineering and Performance: 1–14
Journal of Materials Science: 1–23
Materials Chemistry and Physics 275: 125283
Journal of Materials Engineering and Performance: 1–12
Journal of Materials Engineering and Performance: 1–14
Journal of Materials Science: 1–23
Online since: September 2014
Authors: Young Il Jang, Hyun Do Yun, Wan Shin Park, Il Seung Yang, Bae Su Khil
The materials used in this experimental program are PET, PVA and PE reinforcing a cement matrix.
Materials.
In addition, uniaxial tensile tests were performed on the dog-bone shape specimens to examine the effect of fiber combinations on the tensile strain capacity of materials.
Journal of Advanced Concrete technology 2003; 1(3): p.241~52
Materials and Structures 2006; 39: p.547~55
Materials.
In addition, uniaxial tensile tests were performed on the dog-bone shape specimens to examine the effect of fiber combinations on the tensile strain capacity of materials.
Journal of Advanced Concrete technology 2003; 1(3): p.241~52
Materials and Structures 2006; 39: p.547~55
Online since: June 2007
Authors: Chi Fai Cheung, Suet To, Wing Bun Lee
Introduction
Ultra-precision machining technologies include advanced design of machining facilities,
precision control system, nano-metrology, mechanics of cutting, vibration as well as materials
sciences.
The theory of ultra-precision machining has been studied from the perspectives of various disciplines from continuum mechanics, materials science, to computer modeling.
"Materials Induced Vibration in Ultra-precision Machining," Journal of Materials Processing Technology, Vol. 89-90, p.318 (1999)
"A Dynamic Surface Topography Model for the Prediction of Nano-surface Generation in Ultra-precision Machining," International Journal of Mechanical Sciences, Vol. 43, No. 4, p.961 (2001)
"A Microplasticity Analysis of Micro-cutting Force Variation in Ultra-precision Diamond Turning," Trans. of ASME, Journal of Manufacturing Science and Engineering, Vol. 124, No. 2, p.170-177 (2002)
The theory of ultra-precision machining has been studied from the perspectives of various disciplines from continuum mechanics, materials science, to computer modeling.
"Materials Induced Vibration in Ultra-precision Machining," Journal of Materials Processing Technology, Vol. 89-90, p.318 (1999)
"A Dynamic Surface Topography Model for the Prediction of Nano-surface Generation in Ultra-precision Machining," International Journal of Mechanical Sciences, Vol. 43, No. 4, p.961 (2001)
"A Microplasticity Analysis of Micro-cutting Force Variation in Ultra-precision Diamond Turning," Trans. of ASME, Journal of Manufacturing Science and Engineering, Vol. 124, No. 2, p.170-177 (2002)
Online since: August 2015
Authors: Yong Cheng Liang, Yong Ming Bian, Xiao Mei Liu
Introduction
All kinds of different brittle materials such as ceramics, functional material are used widely in aeronautics, waterdipper and auto-mobile etc fields.
The failures of materials can be classified into two types: brittle fracture and plastic deformation according to the classical strength theory of which the former is affected mainly by traction stress and the latter is deviator strain energy density.
Journal of Mechanics Science and Technology,2008,22: 1269-1278 [6] A.
Material and design, 2010,31: 60-67 [9] A.
International Journal of Fracture, 2004,127: 239~264 [19]Zhang J., Zhao YX., “Resive for the theory of strain energy density factor”, Journal of Baoji College of Arts and Science(Natural Science), 16,1996,pp.70-74 [20] X.M.
The failures of materials can be classified into two types: brittle fracture and plastic deformation according to the classical strength theory of which the former is affected mainly by traction stress and the latter is deviator strain energy density.
Journal of Mechanics Science and Technology,2008,22: 1269-1278 [6] A.
Material and design, 2010,31: 60-67 [9] A.
International Journal of Fracture, 2004,127: 239~264 [19]Zhang J., Zhao YX., “Resive for the theory of strain energy density factor”, Journal of Baoji College of Arts and Science(Natural Science), 16,1996,pp.70-74 [20] X.M.
Online since: February 2014
Authors: Nandy Putra, Rosari Saleh, Wayan Nata Septiadi, Rardi Artono Koestoer, Suhendro Purbo Prakoso
Introduction
Materials with porous structures or porous media, have been giving massive advantages in developing heat pipe as one of heat exchangers especially for the evaporator and the condenser.
Jung-Chang Wang : International Journal of Thermal Sciences 50 (2011), p. 97-105 [10].
Liu : Journal of Porous Materials 4 (1997), p. 303–308 [22].
Ran Bao : International Journal of Thermal Sciences 49 (2010), p. 1680-1687 [28].
Okta D, Zein Hamid, Thermal performance of nanofluids in biomaterial wick loop heat pipes, submitted to International Journal of Thermal Sciences
Jung-Chang Wang : International Journal of Thermal Sciences 50 (2011), p. 97-105 [10].
Liu : Journal of Porous Materials 4 (1997), p. 303–308 [22].
Ran Bao : International Journal of Thermal Sciences 49 (2010), p. 1680-1687 [28].
Okta D, Zein Hamid, Thermal performance of nanofluids in biomaterial wick loop heat pipes, submitted to International Journal of Thermal Sciences
Online since: March 2019
Authors: Mohibah Musa, Haslilywati Ghani, Siti Fatma Abd Karim, Jefri Jaapar, Roslim Ramli
Journal Applied Polymer Science, 96, 1550-1556.
,[] Mohamad Akmal, A.
ARPN Journal of Engineering and Applied Sciences. 11 (2016) 128 -134. ].
Maejo International Journal of Science and Technology. 6 (2012) 249-258. ].
International Research Journal of Advanced Engineering and Sciences. 1 (2016) 71-75. ].
International Journal of Physics Sciences, 2 (2007) 039-046. ].
ARPN Journal of Engineering and Applied Sciences. 11 (2016) 128 -134. ].
Maejo International Journal of Science and Technology. 6 (2012) 249-258. ].
International Research Journal of Advanced Engineering and Sciences. 1 (2016) 71-75. ].
International Journal of Physics Sciences, 2 (2007) 039-046. ].
Online since: May 2006
Authors: Altino Loureiro, Dulce Maria Esteves Rodrigues, Pedro Teixeira
Loureiro: Fracture toughness of welds - effect of brittle zones and strength
mismatch, Journal of Materials Processing Technology 153-154 (2004), p. 537-543
Kim: Determination of microstructural criterion for cryogenic toughness variation in actual HAZs using microstructure-distribution maps, Materials Science and Engineering A351 (2003), p. 183-189
Teodosiu: Three-dimensional numerical simulation of the deep-drawing process using solid finite elements, Journal of Materials Processing Technology 97 (2000), p. 100106
Accepted to Materials Science Forum
Welding Journal, 69(9) (1989): 356s-362s
Kim: Determination of microstructural criterion for cryogenic toughness variation in actual HAZs using microstructure-distribution maps, Materials Science and Engineering A351 (2003), p. 183-189
Teodosiu: Three-dimensional numerical simulation of the deep-drawing process using solid finite elements, Journal of Materials Processing Technology 97 (2000), p. 100106
Accepted to Materials Science Forum
Welding Journal, 69(9) (1989): 356s-362s
Online since: October 2012
Authors: Lian He Yang, Hui Xiao Bai, Shu Sheng Jia
Experiment and Materials
2.1 Experimental materials
The wool yarns and slenderizing yarns was used as raw materials respectively, then knitted on the by the same process parameters, whose specification was plain stitch, 16-pin and the density was 15 mesh/ inch.
Huang, in: Textile Materials, edtied by China Textile& Apparel Press Publishing, China, BJ (1988), in press
Li: submitted to Wool Textile Journal (2003) [4] H.L.
Huang, in: Wool science and technology, edtied by Wool head publishing, English, London (2000), in press
Wu: submitted to Journal of SHANGHAI WOOL & JUTE (2006)
Huang, in: Textile Materials, edtied by China Textile& Apparel Press Publishing, China, BJ (1988), in press
Li: submitted to Wool Textile Journal (2003) [4] H.L.
Huang, in: Wool science and technology, edtied by Wool head publishing, English, London (2000), in press
Wu: submitted to Journal of SHANGHAI WOOL & JUTE (2006)
Online since: June 2020
Authors: Marco Antonio Paredes, Cristian A. Paredes, Christian G Bautista, Patricio I. Mena
Materials and specimen's construction.
International Journal of Innovation and Applied Studies.
Composites manufacturing: Materials, product and process enginering.
Composite Materials, Science and Applications.
Materials Selection in Mechanical Design.
International Journal of Innovation and Applied Studies.
Composites manufacturing: Materials, product and process enginering.
Composite Materials, Science and Applications.
Materials Selection in Mechanical Design.