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Online since: July 2017
Authors: Ekaterina Nosova, Natalia Galkina, Andrey V. Balyakin
Key Engineering Materials 684 (2016) 316-22
[3] G.
Beibei, Finite element simulation and experimental investigation of residual stresses in selective laser melted Ti–Ni shapememory alloy Computational Materials Science 117 (2016) 221-232 [4] A.V.
Materials Science: Textbook for technical colleges and universities, in B.N.
Göken, Improved creep strength of nickel-base superalloys by optimized γ/γ′ partitioning behavior of solid solution strengthening elements, Materials Science and Engineering A 676 (2016) 411-420 [17] Y.
Brochu, Effect of heat treatments on microstructure evolution and mechanical properties of blended nickel-based superalloys powders fabricated by laser powder deposition, Materials Science and Engineering A 674 (2016) 646-657 [18] Q.
Beibei, Finite element simulation and experimental investigation of residual stresses in selective laser melted Ti–Ni shapememory alloy Computational Materials Science 117 (2016) 221-232 [4] A.V.
Materials Science: Textbook for technical colleges and universities, in B.N.
Göken, Improved creep strength of nickel-base superalloys by optimized γ/γ′ partitioning behavior of solid solution strengthening elements, Materials Science and Engineering A 676 (2016) 411-420 [17] Y.
Brochu, Effect of heat treatments on microstructure evolution and mechanical properties of blended nickel-based superalloys powders fabricated by laser powder deposition, Materials Science and Engineering A 674 (2016) 646-657 [18] Q.
Online since: June 2021
Authors: Ping Ping Wu, Bing Rui Xing
Phase Field Simulation on the Surface Morphology of Cu/Ti Nano Thin Film
Pingping Wua* and Bingrui Xingb
Department of Materials Science and Engineering, Xiamen Institute of Technology, No. 1251, Sunban S.
To achieve optimized thin film structure, computer simulation is a very good choice, it can reveal the relationship between the structures and properties of the materials, and accelerate the development of new materials and devices.
Steinbach, Phase-field models in materials science, Modelling and Simulation in Materials Science and Engineering. 2009, 17, 073001
Li, Effects of buffer layer thickness on the surface roughness of In0.3Ga0.7As thin films: A phase-field simulation, Journal of Materials Research, 2013, 28(23), 3218- 3225 [12] P.
Pang, A Phase-Field Model for Multilayered Heterostructure Morphology, Materials science forum. 2019, 944, 788-794
To achieve optimized thin film structure, computer simulation is a very good choice, it can reveal the relationship between the structures and properties of the materials, and accelerate the development of new materials and devices.
Steinbach, Phase-field models in materials science, Modelling and Simulation in Materials Science and Engineering. 2009, 17, 073001
Li, Effects of buffer layer thickness on the surface roughness of In0.3Ga0.7As thin films: A phase-field simulation, Journal of Materials Research, 2013, 28(23), 3218- 3225 [12] P.
Pang, A Phase-Field Model for Multilayered Heterostructure Morphology, Materials science forum. 2019, 944, 788-794
Online since: August 2014
Authors: Kim Song Tan
However, no comparison can be made due to differences in raw materials as compared to this study.
Colloid and Polymer Science 283(5): 570-574
Journal of Rubber Research 14(3): 139-150
Materials Letters 61(28): 5050-5052
Materials Science & Engineering C-Biomimetic and Supramolecular Systems 27(1): 80-82
Colloid and Polymer Science 283(5): 570-574
Journal of Rubber Research 14(3): 139-150
Materials Letters 61(28): 5050-5052
Materials Science & Engineering C-Biomimetic and Supramolecular Systems 27(1): 80-82
Online since: July 2025
Authors: Nurhafizah Abu Talip Yusof, Nur Sofia Idayu Didik Aprianto, Mohamad Khalid Zakarzan, Nurulfadzilah Hasan, Mohamad Shaiful Abdul Karim
Even though these materials are effective, they present environmental challenges due to their non-biodegradable properties.
Formulation of dielectric composite material from raw materials until material characterization.
Yusof, Effect of carbon composition on permittivity performance of dielectric material from agricultural waste, Materials Today: Proceedings, 2023
Karim, Fabrication of Cellulose Powder Dielectric Composite Material using Pineapple Leaves Fiber, Journal of Advanced Research in Applied Sciences and Engineering Technology, 38(2), 2024, 1-15
Kennady Shaju Singh, Characterization of new natural cellulosic fibers–a comprehensive review, IOP Conference Series: Materials Science and Engineering, vol. 574, no. 1, 2019, pp. 01201
Formulation of dielectric composite material from raw materials until material characterization.
Yusof, Effect of carbon composition on permittivity performance of dielectric material from agricultural waste, Materials Today: Proceedings, 2023
Karim, Fabrication of Cellulose Powder Dielectric Composite Material using Pineapple Leaves Fiber, Journal of Advanced Research in Applied Sciences and Engineering Technology, 38(2), 2024, 1-15
Kennady Shaju Singh, Characterization of new natural cellulosic fibers–a comprehensive review, IOP Conference Series: Materials Science and Engineering, vol. 574, no. 1, 2019, pp. 01201
Online since: November 2011
Authors: Yan Ma, Chun Mei Yang, Dong Xia Yang
In the processing of the ultrafine wood powders the raw materials should be dried at first, because the wood fiber is brittle in the low-water-content and which is in favor of the processing.
When the ultrafine powders is being processed using the Japan cedar as the experimental materials, take the cutter diameter D=280mm, the main shaft speed of the cutter n=7000r/min, the cutting angle δ=5°.
China Acknowledgements This work was financially supported by the National Natural Science Foundation of China (30800869) and the National Natural Science Foundation of China (31070500) and Natural Science Foundation of Heilongjiang Province (C201018) and Central university basic research special fund operating expenses (DL09BB14).
[2] Li Jian: Wood Science, Harbin, Northeast Forestry University Press, 1994, 12
[5] Piao Yongshou: Wood Cutting Science, Harbin, Northeast Forestry University Press, 1992, 7
When the ultrafine powders is being processed using the Japan cedar as the experimental materials, take the cutter diameter D=280mm, the main shaft speed of the cutter n=7000r/min, the cutting angle δ=5°.
China Acknowledgements This work was financially supported by the National Natural Science Foundation of China (30800869) and the National Natural Science Foundation of China (31070500) and Natural Science Foundation of Heilongjiang Province (C201018) and Central university basic research special fund operating expenses (DL09BB14).
[2] Li Jian: Wood Science, Harbin, Northeast Forestry University Press, 1994, 12
[5] Piao Yongshou: Wood Cutting Science, Harbin, Northeast Forestry University Press, 1992, 7
Online since: May 2009
Editor Note
It is a pleasure for me to serve as guest editor for a special issue of Materials
Science Forum entitled "Deformation Processes of Rigid Plastic Materials".
I would like to thank the editor of the journal and all the authors for their contributions and for patience.
Sergei Alexandrov Institute for Problems in Mechanics Russian Academy of Sciences 101-1 Prospect Vernadskogo 119526 Moscow, Russia Tel.: +7 495 4343665; fax: +7 499 739 9531 E-mail address: sergei_alexandrov@yahoo.com
I would like to thank the editor of the journal and all the authors for their contributions and for patience.
Sergei Alexandrov Institute for Problems in Mechanics Russian Academy of Sciences 101-1 Prospect Vernadskogo 119526 Moscow, Russia Tel.: +7 495 4343665; fax: +7 499 739 9531 E-mail address: sergei_alexandrov@yahoo.com
Online since: November 2012
Authors: Péter Nagy, Bálint Katona, Kristóf Hirschberg, Eszter Bognár
Development of nitinol stents: etching experiments
Bálint Katona1,a, Péter Nagy1,b, Eszter Bognár1,c, Kristóf Hirschberg2,3,d
1Budapest University of Technology and Economics
Department of Materials Science and Engineering.
Peripheral stent materials.
Journal of Materials Processing Technology 2010; 210: 1918–1925 [7] MH Elahinia, M Hashemi, M Tabesh et al.: Manufacturing and processing of NiTi implants: A review.
Progress in Materials Science xxx 2011; xxx–xxx doi:10.1016/j.pmatsci.2011.11.001
Journal of Materials Processing Technology 2005; 170: 545–550 [9] A Stephen: Mechanisms and Applications of Laser Chemical Machining.
Peripheral stent materials.
Journal of Materials Processing Technology 2010; 210: 1918–1925 [7] MH Elahinia, M Hashemi, M Tabesh et al.: Manufacturing and processing of NiTi implants: A review.
Progress in Materials Science xxx 2011; xxx–xxx doi:10.1016/j.pmatsci.2011.11.001
Journal of Materials Processing Technology 2005; 170: 545–550 [9] A Stephen: Mechanisms and Applications of Laser Chemical Machining.
Online since: January 2015
Authors: Lin Jie Li, Jia Liang Liu
Acknowledgement
This paper was supported by the foundation of National and Local Joint Engineering Laboratory of Traffic Civil Engineering Materials (Project No.
Fire Safety Journal, 2010 45(2) 142-148
Fire Safety Journal, 2008 (43) 344-350
Fire Safety Journal, 2005 (40) 267-281
Progress in Safety Science and Technology, 2008 (12) 679-683
Fire Safety Journal, 2010 45(2) 142-148
Fire Safety Journal, 2008 (43) 344-350
Fire Safety Journal, 2005 (40) 267-281
Progress in Safety Science and Technology, 2008 (12) 679-683
Online since: March 2010
Authors: Hao Bin Tian, Xiao Hang Liu, Jian Ping Lin
Ni, etc: Chinese Journal of Mechanical Engineering, Vol.38 (2002), p.3 (In
Chinese)
[2] Materials & Processes.
Liu, etc: Journal of Tongji University (Natural Science).
Dissertation for Doc Degree, Northwest University, (2001) [7] M.B.Silva, M.Skioedt, P.Vilaca, N.Bay, P.A.F.Martins: Journal of Materials Processing Technology.
Sheng: Journal of Materials Processing Technology, Vol.205 (2008), p.81 [9] S.K.
Kumar: Journal of Materials Processing Technology, Vol. 204 (2008), p.70
Liu, etc: Journal of Tongji University (Natural Science).
Dissertation for Doc Degree, Northwest University, (2001) [7] M.B.Silva, M.Skioedt, P.Vilaca, N.Bay, P.A.F.Martins: Journal of Materials Processing Technology.
Sheng: Journal of Materials Processing Technology, Vol.205 (2008), p.81 [9] S.K.
Kumar: Journal of Materials Processing Technology, Vol. 204 (2008), p.70
Online since: March 2013
Authors: Jae Hyouk Choi, Daniel Yeshewawork Abebe
Material Model: The analysis is modeled as a shell element with nonlinear, inelastic plastic kinematics characteristics of material.
It is evident that the strain-hardening effect has important influence on the non-linear behavior of materials.
Acknowledgements This work was financially supported by Basic Science Research Program through the National Research Foundation of Korea (NRF) funded by the Ministry of Education, Science and Technology (No.2012-0008837, No.2012-0004069) References [1] D.
F.R, Inelastic Column Theory, Journal of Aeronautical Science; 1947; 14, p.261-264 [7] Daisuke ST, Ahmer WD, Post-buckling Behavior of Pre-stressed Steel Stayed Columns, Engineering Structures; 2008; 30, 1224-1239 [8] ANSYS LS-Dyna User manual [9] Hyunhoon C, Jinkoo K.
Limit Design of Columns, Journal of the Aeronautical Sciences; 1954. 21, p.43~49 [15] Kyung Koo L, Evaluation of Residual Capacity of Steel Compressive Members under Blast Load, Journal of Architectural Institute of Korea; 2010; 264, 37-44
It is evident that the strain-hardening effect has important influence on the non-linear behavior of materials.
Acknowledgements This work was financially supported by Basic Science Research Program through the National Research Foundation of Korea (NRF) funded by the Ministry of Education, Science and Technology (No.2012-0008837, No.2012-0004069) References [1] D.
F.R, Inelastic Column Theory, Journal of Aeronautical Science; 1947; 14, p.261-264 [7] Daisuke ST, Ahmer WD, Post-buckling Behavior of Pre-stressed Steel Stayed Columns, Engineering Structures; 2008; 30, 1224-1239 [8] ANSYS LS-Dyna User manual [9] Hyunhoon C, Jinkoo K.
Limit Design of Columns, Journal of the Aeronautical Sciences; 1954. 21, p.43~49 [15] Kyung Koo L, Evaluation of Residual Capacity of Steel Compressive Members under Blast Load, Journal of Architectural Institute of Korea; 2010; 264, 37-44