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Online since: January 2018
Authors: E.M. Shpilevsky, O Penyazkov, S. Filatov, G. Shilagardi, P. Tuvshintur, D. Timur-Bаtor, D. Ulam-Orgikh
Modification of Materials by Carbon Nanoparticles
E.
Fullerenes and fullerene-like structures: the basis for promising materials // Journal of Engineering Physics and Thermophysics. 2001.
An International Journal. 2013, Vol.4, No4.
Containing carbon nanoparticles materials in hydrogen energy.
Fullerene-containing materials and functional elements based on them.
Fullerenes and fullerene-like structures: the basis for promising materials // Journal of Engineering Physics and Thermophysics. 2001.
An International Journal. 2013, Vol.4, No4.
Containing carbon nanoparticles materials in hydrogen energy.
Fullerene-containing materials and functional elements based on them.
Online since: January 2013
Authors: Xiu Rong Li, Tao Jiang, Jing Sun, Yun Lin Fu, Zhi Hua Xie, De Hua Li
Materials and methods
2.1 Main materials and equipment
(1) Raw material, air-seasoning Trema orientalis, is collected from Dali of Yunnan and processed into 60 mesh wood flour. (2) Ionic liquid, AMIM] Cl, is purchased from Shanghai Boyle Chemical Co., Ltd.; (3) Magnetic stirrer and magneton; (4) Experimental vacuum oven.
2.2 Dissolve the cellulose with the ionic liquid
Put the extracted wood flour in the vacuum oven at 80℃ and with the pressure of 0.04MPa, and then dry it.
Journal of Applied Polymer Science, 2011, 119(6): 3207–3216
Materials Research Innovations, 2011, 15, Suppl 1: 446-449
Journal of Applied Polymer Science, 2012, Doi: 10.1002/app.38099 [7] Yongfeng Li, Yixing Liu*, FenghuWang, Xiangming Wang.
Evaluation of the Surface Roughness of Wood-based Environmental Materials and its Impact on Human Psychology and Physiology, Advanced Materials Research Vols.113-114 (2010) p 932-937 [9] Przemyslaw Kubisa.
Journal of Applied Polymer Science, 2011, 119(6): 3207–3216
Materials Research Innovations, 2011, 15, Suppl 1: 446-449
Journal of Applied Polymer Science, 2012, Doi: 10.1002/app.38099 [7] Yongfeng Li, Yixing Liu*, FenghuWang, Xiangming Wang.
Evaluation of the Surface Roughness of Wood-based Environmental Materials and its Impact on Human Psychology and Physiology, Advanced Materials Research Vols.113-114 (2010) p 932-937 [9] Przemyslaw Kubisa.
Online since: September 2007
Authors: Ming Chen, Y.G. Wang, Di Zhang
The hard phase Mo2FeB2 is
formed during casting process because there is no Mo2FeB2 in the raw materials.
Progress in Materials Science, Vol.48, n2 (2003), p. 57-170 [3] H.
Materials Research Bulletion, vol.37, n3(2002), p. 417-423 [8] Y.G.
Chinese Journal of Applied Mechanics, Vol.19, n3 (2002), p.120-123 [10] R.M.
P/M Science &Technology Briefs, Vol.2, n4 (2002), p. 9-13 [12] T.
Progress in Materials Science, Vol.48, n2 (2003), p. 57-170 [3] H.
Materials Research Bulletion, vol.37, n3(2002), p. 417-423 [8] Y.G.
Chinese Journal of Applied Mechanics, Vol.19, n3 (2002), p.120-123 [10] R.M.
P/M Science &Technology Briefs, Vol.2, n4 (2002), p. 9-13 [12] T.
Online since: December 2011
Authors: Wei Wei Yu, Xuan Guo
Damage Model for Dissipative Materials with Generalized Non-Linear Strength Theory
YU WeiWei1, a, GUO Xuan2,b
1School of statistics, Capital university of economics and business, Beijing, 100070, China
2School of Civil Engineering, Beijing Jiaotong University, Beijing 100044, China
awowo8830@163.com, bxguo@bjtu.edu.cn
Keywords: damage model, dissipative materials, generalized non-linear strength theory
Abstract.
This paper builds the formulations of damage model for dissipative materials with generalized non-linear strength theory.
Recently, the time-independent constitutive modeling for porous and multi-phase nanocrystalline materials and a simple phenomenological model for describing the macroscopic constitutive response of ferroelectric materials have been developedin the correlative field.
Chaboche,J.L.Mechanics of solid materials.
Yu,, Chinese Journal of Geotechnical En-gineering (in Chinese), Vol.16(2) (1994), p. 1
This paper builds the formulations of damage model for dissipative materials with generalized non-linear strength theory.
Recently, the time-independent constitutive modeling for porous and multi-phase nanocrystalline materials and a simple phenomenological model for describing the macroscopic constitutive response of ferroelectric materials have been developedin the correlative field.
Chaboche,J.L.Mechanics of solid materials.
Yu,, Chinese Journal of Geotechnical En-gineering (in Chinese), Vol.16(2) (1994), p. 1
Online since: July 2022
Authors: Olga Skorodumova, Olena Tarakhno, Andrey Sharshanov, Atabala M. Babayev
Materials Science Forum, 1038 (2021) 460-467
Materials Science Forum, 1038 (2021) 235-241
Materials Science Forum, 1038 (2021) 468-479
Materials Science Forum, 1006 (2020) 70-75
Materials Science Forum, 1006 (2020) 25-31
Materials Science Forum, 1038 (2021) 235-241
Materials Science Forum, 1038 (2021) 468-479
Materials Science Forum, 1006 (2020) 70-75
Materials Science Forum, 1006 (2020) 25-31
Online since: November 2019
Authors: Y. Nagaraj, N. Jagannatha, N. Sathisha
References
[1] J.P.Choi, B.H.Jeon, B.H.Kim: Journal of Materials Processing Technology,191(2007),p.153-156
[2] Dae Kyun Baek, Tae Jo Ko, Seung Han Yang: Journal of Materials Processing Technology, 213(2013), p.553– 559
[3] Jianjian Wang , Jianfu Zhang , Pingfa Feng , Ping Guo: International Journal of Mechanical Sciences, (2017)
[4] Dong-Sam Park, Myeong-Woo Chob, Honghee Lee, Won-Seung Cho, 146(2004), p.234-240
[5] Kumar Abhisheka, Somashekhar S.
Ahsan: J. of materials processing technology., 198( 2 0 0 8 ) p.122–128 [11] Ushasta Aicha, Simul Banerjee, Asish Bandyopadhyay, Probal Kumar Das: Procedia Materials Science, 6 ( 2014 ), p. 775 – 785 [12] K.
Razfar: Journal of Materials Processing Tech, 255 (2018), p. 665–672 [23] Sathisha N, Somashekar S.Hiremath, Shivakumar J: International Journal of Recent advances in Mechanical Engineering.
Sharma, Pradeep Kumar, Shantanu Das, International Journal of Industrial Engineering and Management Science, Vol. 4, (2014), No. 3 [40] Nitin K.
Sharma, Pradeep Kumar, Shantanu Das, Journal of Materials Processing Technology 225(2015), p. 151–161
Ahsan: J. of materials processing technology., 198( 2 0 0 8 ) p.122–128 [11] Ushasta Aicha, Simul Banerjee, Asish Bandyopadhyay, Probal Kumar Das: Procedia Materials Science, 6 ( 2014 ), p. 775 – 785 [12] K.
Razfar: Journal of Materials Processing Tech, 255 (2018), p. 665–672 [23] Sathisha N, Somashekar S.Hiremath, Shivakumar J: International Journal of Recent advances in Mechanical Engineering.
Sharma, Pradeep Kumar, Shantanu Das, International Journal of Industrial Engineering and Management Science, Vol. 4, (2014), No. 3 [40] Nitin K.
Sharma, Pradeep Kumar, Shantanu Das, Journal of Materials Processing Technology 225(2015), p. 151–161
Online since: November 2011
Edited by: Akii Okonigbon Akaehomen Ibhadode
This periodical edition includes peer-reviewed papers based on results of scientific research and engineering solutions in different areas of modern engineering science.
Keywords:
Materials Science, Materials, Mechanics, Civil Engineering, Electrical Engineering, Cumputer Science, Environmental Engineering
Keywords:
Materials Science, Materials, Mechanics, Civil Engineering, Electrical Engineering, Cumputer Science, Environmental Engineering
Online since: July 2020
Authors: Xiang Li, Liang Zhao, Qian Huang, Hua Yin Sun
Experimental Method and Process
Raw Materials.
Effects of temperature gradient on the damage of zirconia metering nozzle, International Journal of Minerals, Metallurgy, and Materials, 2017, 24(9): 999-1003
Effects of the Precipitation of Stabilizers on the Mechanism of Grain Fracturing in a Zirconia Metering Nozzle, International Journal of Minerals, Metallurgy, and Materials, 2016, 23(9): 1041-1047
Effect of Various Surface Treatments on the Bond Strength Between Composite Resin and Zirconia Veneering Ceramic, Science of Advanced Materials, 2015, 7(1): 57-62
Corrosion Mechanism of Calcium Oxide Partially Stabilized Zirconia by an Alkaline Steel Slag, Science of Advanced Materials, 2019, 11(4): 483-488
Effects of temperature gradient on the damage of zirconia metering nozzle, International Journal of Minerals, Metallurgy, and Materials, 2017, 24(9): 999-1003
Effects of the Precipitation of Stabilizers on the Mechanism of Grain Fracturing in a Zirconia Metering Nozzle, International Journal of Minerals, Metallurgy, and Materials, 2016, 23(9): 1041-1047
Effect of Various Surface Treatments on the Bond Strength Between Composite Resin and Zirconia Veneering Ceramic, Science of Advanced Materials, 2015, 7(1): 57-62
Corrosion Mechanism of Calcium Oxide Partially Stabilized Zirconia by an Alkaline Steel Slag, Science of Advanced Materials, 2019, 11(4): 483-488
Online since: March 2021
Authors: Sunchul Huh, Hyunji Kim, Haneul Kang, Sunghoon Im, Jinho Yang
Materials and Methods
Manufacture of Thermal Grease.
Acknowledgments This project was supported by the Basic Science Research Program through the National Research Foundation of Korea (NRF) funded by the Ministry of Science, ICT and future Planning (No. 2018R1A5A5A05022883) References [1] Moore, A.L. and Shi, L., “Emerging challenges and materials for thermal management of electronics” Materials today, vol. 17, no. 4, (2014), pp. 163-174, [2] Chung, D.D.L., Thermal interface materials, Journal of Materials Engineering and Performance, 10(1), (2001), pp. 56-59
Webb, Performance and testing of thermal interface materials, Microelectron.
[5] Prasher, R., Thermal interface materials: historical perspective, status, and future directions.
[16] Wei Yu, Huaqing Xie, Luqiao Yin, Junchang Zhao, Ligang Xia, Lifei Chen, Exceptionally high thermal conductivity of thermal grease: Synergistic effects of graphene and alumina, International Journal of Thermal Sciences 91, Elsevier Science, Amsterdam, (2015), pp. 76-82.
Acknowledgments This project was supported by the Basic Science Research Program through the National Research Foundation of Korea (NRF) funded by the Ministry of Science, ICT and future Planning (No. 2018R1A5A5A05022883) References [1] Moore, A.L. and Shi, L., “Emerging challenges and materials for thermal management of electronics” Materials today, vol. 17, no. 4, (2014), pp. 163-174, [2] Chung, D.D.L., Thermal interface materials, Journal of Materials Engineering and Performance, 10(1), (2001), pp. 56-59
Webb, Performance and testing of thermal interface materials, Microelectron.
[5] Prasher, R., Thermal interface materials: historical perspective, status, and future directions.
[16] Wei Yu, Huaqing Xie, Luqiao Yin, Junchang Zhao, Ligang Xia, Lifei Chen, Exceptionally high thermal conductivity of thermal grease: Synergistic effects of graphene and alumina, International Journal of Thermal Sciences 91, Elsevier Science, Amsterdam, (2015), pp. 76-82.
Online since: May 2021
Authors: Akram R. Jabur, Ahmed H. Oleiwi, Qusay F. Alsalhy
Journal of membrane science 394 (2012): 37-48
Biomedical Materials 13.1 (2017): 015010
Journal of materials science 41.17 (2006): 5704-5708
International Journal of Thin Films Science and Technology 5.2 (2016): 1-9
Karbala International Journal of Modern Science 1.4 (2015): 187-193
Biomedical Materials 13.1 (2017): 015010
Journal of materials science 41.17 (2006): 5704-5708
International Journal of Thin Films Science and Technology 5.2 (2016): 1-9
Karbala International Journal of Modern Science 1.4 (2015): 187-193