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Online since: November 2015
Authors: Krishnamoorthy Balachandar, Sivachidambaram Pichumani
Froyen, 2003, Microstructure and interface characteristics of B4C, SiC and Al2O3 reinforced Al matrix composites - a comparative study, Journal of Materials Processing Technology, 142, pp 738-743.
Looney,2004, Development and assessment of new quick quench stir caster design for the production of metal matrix composites, Journal of Materials Processing Technology, 106, pp 430-439.
Hashmi, 1999, Metal matrix composites: Production by the stir casting method, Journal of Materials Processing Technology, Volume 92-93, 1999, pp 1-7.
Prasad Rao,2007, Effect of scandium additions on microstructure and mechanical properties of Al-Zn-Mg alloy welds, Materials Science and Engineering A, 467, pp132-138.
Prasad Rao, 2005, Grain refinement through arc manipulation techniques in Al-Cu alloy GTA welds, Materials Science and Engineering A, 404, pp 227 - 234.
Looney,2004, Development and assessment of new quick quench stir caster design for the production of metal matrix composites, Journal of Materials Processing Technology, 106, pp 430-439.
Hashmi, 1999, Metal matrix composites: Production by the stir casting method, Journal of Materials Processing Technology, Volume 92-93, 1999, pp 1-7.
Prasad Rao,2007, Effect of scandium additions on microstructure and mechanical properties of Al-Zn-Mg alloy welds, Materials Science and Engineering A, 467, pp132-138.
Prasad Rao, 2005, Grain refinement through arc manipulation techniques in Al-Cu alloy GTA welds, Materials Science and Engineering A, 404, pp 227 - 234.
Online since: July 2016
Authors: John Phillip Carter, Majidreza Nazem, Javad Ghorbani
ajavad.ghorbani@uon.edu.au, b majidreza.nazem@newcastle.edu.au, cjohn.carter@newcastle.edu.au
Keywords: Dynamic compaction, Unsaturated soils, Soil dynamics, Finite element, Multi-phase materials, Porous Media, Absorbing boundary condition
Abstract.
Mathematical and Physical Sciences. 429(1877) (1990) 285-309
International journal for numerical and analytical methods in geomechanics. 27(9) (2003) 745-765
Canadian Geotechnical Journal. 45(4) (2008) 511-534
Journal of the Engineering Mechanics Division. 95(4) (1969) 859-878
Mathematical and Physical Sciences. 429(1877) (1990) 285-309
International journal for numerical and analytical methods in geomechanics. 27(9) (2003) 745-765
Canadian Geotechnical Journal. 45(4) (2008) 511-534
Journal of the Engineering Mechanics Division. 95(4) (1969) 859-878
Online since: July 2012
Authors: Min Zhang, Qian Ma, Jian Wang
Materials and methods
Materials and chemicals.
Acknowledgements This research was supported by the National Natural Science Foundation of China (30972042).
Journal of Chinese Medicinal Materials, 27 8 (2004), p. 599-600
Journal of Life Sciences, 76 (2004), p. 137-149
Journal of Chinese Medicinal Materials, 2(2007), p.155-157 , in Chinese
Acknowledgements This research was supported by the National Natural Science Foundation of China (30972042).
Journal of Chinese Medicinal Materials, 27 8 (2004), p. 599-600
Journal of Life Sciences, 76 (2004), p. 137-149
Journal of Chinese Medicinal Materials, 2(2007), p.155-157 , in Chinese
Online since: August 2023
Authors: Lia-Nicoleta Botila, Eduard Laurentiu Nitu, Daniela Monica Iordache, Tatiana Georgescu
Jain, Fundamentals of Friction Stir Welding, Its Application and Advancements, Materials Forming, in: J.P.
Bhatnagar Friction Stir Spot Welding of advanced high-strength steels - A feasibility study, SAE International, Journal of Materials and Manufacturing, 2005-01-1248, 2005
Cho, H.N.Han, Behaviors of Friction Stir Spot Welded Joints of Dissimilar Ferrous Alloys under Opening-Dominant Combined Loads, Hindawi Publishing Corporation, Advances in Materials Science and Engineering 1 (2014) 1-12, http://dx.doi.org/10.1155/2014/572970 [18] H.
Nelson, A review of Friction Stir Welding of steels: tool, material flow, microstructure, and properties, Journal of Materials Science & Technology 34:1 (2018) 39-57
Zhou, Resistance and friction stir spot welding of DP600: a comparative study, Institute of Materials, Minerals and Mining, Science and Technology of Welding and Joining 2, 12 (2007) 175-182 [23] A.
Bhatnagar Friction Stir Spot Welding of advanced high-strength steels - A feasibility study, SAE International, Journal of Materials and Manufacturing, 2005-01-1248, 2005
Cho, H.N.Han, Behaviors of Friction Stir Spot Welded Joints of Dissimilar Ferrous Alloys under Opening-Dominant Combined Loads, Hindawi Publishing Corporation, Advances in Materials Science and Engineering 1 (2014) 1-12, http://dx.doi.org/10.1155/2014/572970 [18] H.
Nelson, A review of Friction Stir Welding of steels: tool, material flow, microstructure, and properties, Journal of Materials Science & Technology 34:1 (2018) 39-57
Zhou, Resistance and friction stir spot welding of DP600: a comparative study, Institute of Materials, Minerals and Mining, Science and Technology of Welding and Joining 2, 12 (2007) 175-182 [23] A.
Online since: September 2014
Authors: Petr Valášek, Miroslav Müller
Biocomposite based on epoxy resin and Jatropha curcas L. microparticles
Petr Valášek1, a, Miroslav Müller1, b
1Czech University of Life Sciences Prague, Department of Material Science and Manufacturing Technology
avalasekp@tf.czu.cz, bmuller@tf.czu.cz
Keywords: adhesion, cohesion, hardness, lap-shear strength, tensile strength.
A development of composite materials – biocomposites from renewable resource is an interesting and prospective tendency of a material engineering.
Biocomposites are composite materials comprising one or more phase(s) derived from a biological origin [3].
International Journal of Green Energy Vol. 11(2) (2014), p. 193-205 [2] D.
A Jatropha biomass as renewable materials for biocomposites and its applications.
A development of composite materials – biocomposites from renewable resource is an interesting and prospective tendency of a material engineering.
Biocomposites are composite materials comprising one or more phase(s) derived from a biological origin [3].
International Journal of Green Energy Vol. 11(2) (2014), p. 193-205 [2] D.
A Jatropha biomass as renewable materials for biocomposites and its applications.
Online since: May 2020
Authors: Liana K. Karimova, Alsu I. Akhmetshina, T.R. Deberdeev
Introduction
The continuous development of modern high-technology industries (space, micro- and nanoelectronics, planes, automotive, fuel cells, etc.) is closely related to state-of-the-art investigations of materials and the recent advances in polymer science.
Active research and implementation of polymeric materials almost in all areas of engineering and technology have replaced a plethora of natural and artificial materials.
In this case, neat TA and 4-HBA were used as starting materials.
Kimura, Preparation of poly(p‐oxybenzoyl) crystals using direct polymerization of p‐hydroxybenzoic acid in the presence of boronic anhydrides, Journal of Polymer Science Part A: Polymer Chemistry. 49 (2011) 1088-1096
Wright, Heat-Resistant Polymers: Technologically Useful Materials, Springer science+Business media, New York, 1983
Active research and implementation of polymeric materials almost in all areas of engineering and technology have replaced a plethora of natural and artificial materials.
In this case, neat TA and 4-HBA were used as starting materials.
Kimura, Preparation of poly(p‐oxybenzoyl) crystals using direct polymerization of p‐hydroxybenzoic acid in the presence of boronic anhydrides, Journal of Polymer Science Part A: Polymer Chemistry. 49 (2011) 1088-1096
Wright, Heat-Resistant Polymers: Technologically Useful Materials, Springer science+Business media, New York, 1983
Online since: August 2024
Authors: Mohamed Azzaz, Warda Laslouni, Ahmed Haddad, Hanane Mechri, Zineb Hamlati
The Cu70 Fe30 samples were elaborated and compacted at Materials Science and Engineering Laboratory, USTHB.The formatting process consisted of two steps.
This analysis, XRD and SEM were also carried out at the Materials Science and Engineering Laboratory.
International Journal of Computational and Experimental Science and Engineering 2(2): 24– 27
Emerging Materials Research (2019) 8(4): 552–557
Taekim, materials sciences and engineer A304-306 (2001), pp 928-931
This analysis, XRD and SEM were also carried out at the Materials Science and Engineering Laboratory.
International Journal of Computational and Experimental Science and Engineering 2(2): 24– 27
Emerging Materials Research (2019) 8(4): 552–557
Taekim, materials sciences and engineer A304-306 (2001), pp 928-931
Online since: January 2012
Authors: Mohammad Javad Nategh, H. Soleimanimehr, Hamed Razavi
Andrew, A study on ultrasonic vibration cutting of low alloy steel, Journal of Materials Processing Technology Vol. 192–193 (2007), p. 159
[10] Chandra Nath, M.
Silberschmidt, Analysis of material response to ultrasonic vibration loading in turning Inconel 718, Materials Science and Engineering: A Vol. 424 (2006), p. 318 [14] Jerald L.
Silberschmidt, Finite element simulations of ultrasonically assisted turning, Computational Materials Science Vol. 28 (2003), p. 645 [17] A.V.
Silberschmidt, Finite element analysis of ultrasonically assisted turning of Inconel 718, Journal of Materials Processing Technology Vol. 153–154 (2004), p. 233 [18] V.I.
Silberschmidt, Thermomechanical finite element simulations of ultrasonically assisted turning, Computational Materials Science Vol. 32 (2005), p. 463 [21] N.
Silberschmidt, Analysis of material response to ultrasonic vibration loading in turning Inconel 718, Materials Science and Engineering: A Vol. 424 (2006), p. 318 [14] Jerald L.
Silberschmidt, Finite element simulations of ultrasonically assisted turning, Computational Materials Science Vol. 28 (2003), p. 645 [17] A.V.
Silberschmidt, Finite element analysis of ultrasonically assisted turning of Inconel 718, Journal of Materials Processing Technology Vol. 153–154 (2004), p. 233 [18] V.I.
Silberschmidt, Thermomechanical finite element simulations of ultrasonically assisted turning, Computational Materials Science Vol. 32 (2005), p. 463 [21] N.
Online since: June 2019
Authors: Anuar Mohd Ishak, Ioan Pop, Nor Ain Azeany Mohd Nasir
Khan, Numerical analysis of magnetic field effects on Eyring-Powell fluid flow towards a stretching sheet, Journal of Magnetism and Magnetic Materials 382 (2015) 355–358
Pop, MHD heat and mass transfer flow over a permeable stretching/shrinking sheet with radiation effect, Journal of Magnetism and Magnetic Materials 407 (2016) 235–240
Pop, Boundary-layer flow of nanofluids over a moving surface in a flowing fluid, International Journal of Thermal Sciences 49 (2010) 1663–1668
Nield, Natural convective boundary-layer flow of a nanofluid past a vertical plate, International Journal of Thermal Sciences 49 (2010) 243–247 [16] Y.
Ul Haq, Magnetohydrodynamic (MHD) stagnation point flow of nanofluid past a stretching sheet with convective boundary condition, Journal of the Brazilian Society of Mechanical Sciences and Engineering 38(4) (20136) 1155–1164.
Pop, MHD heat and mass transfer flow over a permeable stretching/shrinking sheet with radiation effect, Journal of Magnetism and Magnetic Materials 407 (2016) 235–240
Pop, Boundary-layer flow of nanofluids over a moving surface in a flowing fluid, International Journal of Thermal Sciences 49 (2010) 1663–1668
Nield, Natural convective boundary-layer flow of a nanofluid past a vertical plate, International Journal of Thermal Sciences 49 (2010) 243–247 [16] Y.
Ul Haq, Magnetohydrodynamic (MHD) stagnation point flow of nanofluid past a stretching sheet with convective boundary condition, Journal of the Brazilian Society of Mechanical Sciences and Engineering 38(4) (20136) 1155–1164.
Online since: March 2015
Authors: Cheng Zhang, Fang Li Duan, Qing Song Liu
Weinkamer, Progress in Materials Science, 52 (2007) 1263-1334
Buehler, Computational Materials Science, 48 (2010) 303-309
Buehler, Advanced Engineering Materials, 13 (2011) B405-B414
Pan, Materials Science & Engineering C-Biomimetic and Supramolecular Systems, 16 (2001) 3-10
Cormack, Chemistry of Materials, 20 (2008) 4356-4366
Buehler, Computational Materials Science, 48 (2010) 303-309
Buehler, Advanced Engineering Materials, 13 (2011) B405-B414
Pan, Materials Science & Engineering C-Biomimetic and Supramolecular Systems, 16 (2001) 3-10
Cormack, Chemistry of Materials, 20 (2008) 4356-4366