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Online since: June 2021
Authors: G. Kishore Chowdari, D.V.V. Krishna Prasad
Journal of Thermoplastic Composite Materials 2020: 33, 324-42
Journal of Materials Research and Technology 2019: 8, 3327-37
Journal of minerals and materials characterization and Engineering 2012: 11, 774-79
Journal of Materials and Environmental Science 2011: 2, 351-56
Journal of Materials and Environmental Science 2016: 7, 1674-80
Journal of Materials Research and Technology 2019: 8, 3327-37
Journal of minerals and materials characterization and Engineering 2012: 11, 774-79
Journal of Materials and Environmental Science 2011: 2, 351-56
Journal of Materials and Environmental Science 2016: 7, 1674-80
Online since: August 2019
Authors: Susilawati Susilawati, Aris Doyan, Muhammad Taufik, Wahyudi Wahyudi, Eryn Ryantin Gunawan, Annisa Fitriani, Nazarudin Nazarudin
One of the materials currently drawing attention to the microwave absorbent material is Barium M-hexaferrite (BaFe12O19) or better known as BaM.
[5] Ratnawulan, Characterization of Natural Iron Ore as a Magnetite Raw Material on Dry Ink, Journal of Science and Mathematics 6 (1) (2013)
[10] Sholihah, F.R., Zainuri, M., Effect of Holding Time Calcination on the Magnetic Properties of Barium M-hexaferrite (BaFe12-xZnxO19) with Ion Doping Zn, ITS Science and Art Journal 1 (1) (2012) 25-29
Sahlam, Synthesis and Characterization Materials M-Barium Hexaferrite Doping Ions Co-Mn Nano Particle, IOP Conf.
Series: Materials Science and Engineering 196 (2017) 012016
[5] Ratnawulan, Characterization of Natural Iron Ore as a Magnetite Raw Material on Dry Ink, Journal of Science and Mathematics 6 (1) (2013)
[10] Sholihah, F.R., Zainuri, M., Effect of Holding Time Calcination on the Magnetic Properties of Barium M-hexaferrite (BaFe12-xZnxO19) with Ion Doping Zn, ITS Science and Art Journal 1 (1) (2012) 25-29
Sahlam, Synthesis and Characterization Materials M-Barium Hexaferrite Doping Ions Co-Mn Nano Particle, IOP Conf.
Series: Materials Science and Engineering 196 (2017) 012016
Online since: February 2006
Authors: D.N. Tsipas, M. Gavaises, I.Ch. Konstantinidis, D.P. Papadopoulos
These
materials have received a lot of attention over the last few years, and they show a great potential for a
wide range of industrial applications.
The mechanical properties of cellular materials depend on their relative densities (microstructure) and cell size-morphology (macrostructure).
Mechanical and heat transfer modeling of cellular materials Mechanical properties modeling.
Banhart, Manufacture, characterization and application of cellular metals and metal foams, Progress in Materials Science Vol. 46 (2001), p. 559- 632
Gibson, Size effects in ductile cellular solids, Part I: modeling, International Journal of Mechanical Sciences Vol. 43 (2001) p.681-699
The mechanical properties of cellular materials depend on their relative densities (microstructure) and cell size-morphology (macrostructure).
Mechanical and heat transfer modeling of cellular materials Mechanical properties modeling.
Banhart, Manufacture, characterization and application of cellular metals and metal foams, Progress in Materials Science Vol. 46 (2001), p. 559- 632
Gibson, Size effects in ductile cellular solids, Part I: modeling, International Journal of Mechanical Sciences Vol. 43 (2001) p.681-699
Online since: February 2018
Authors: Ye Hua Jiang, Quan Shan, Zu Lai Li, Ya Feng Zhang, Fei Zhang, Feng Rui Chen
Journal of Materials Science, 35(24) (2000) 6231-6236
Journal of Materials Science, 26(22) (1991) 5965-5968
Journal of Aeronautical Materials, 33(4) (2013) 27-31
Journal of Materials Research, 31(16) (2016) 2376-2383
Materials Science and Engineering, 81 (1986) 175-179
Journal of Materials Science, 26(22) (1991) 5965-5968
Journal of Aeronautical Materials, 33(4) (2013) 27-31
Journal of Materials Research, 31(16) (2016) 2376-2383
Materials Science and Engineering, 81 (1986) 175-179
Online since: March 2016
Authors: M.A. Khan, Asma Ishaque, Rizwana Mofeed, Tariq Iqbal, Hasan Mahmood, Raja Naveed Ahmed, Ayaz Arif Khan, Mahboobullah Mahboobullah
Zhang M., Xu X., Zhang M., Materials Letters; 2008;62:385-388
[16].
Song X., Yu H., Sun S., Journal of Colloid and Interface Science; 2005;289:588-591 [21].
A. and Longo E., Materials Research Bulletin; 2008;43:771-775 [22].
Xu X., Zhang M., Feng J. and Zhang M., Materials Letters; 2008;62:2787-2790 [23].
G., Fundamentals of Materials Science and Engineering, John Wiley & Sons, third edition, 2007 [25].
Song X., Yu H., Sun S., Journal of Colloid and Interface Science; 2005;289:588-591 [21].
A. and Longo E., Materials Research Bulletin; 2008;43:771-775 [22].
Xu X., Zhang M., Feng J. and Zhang M., Materials Letters; 2008;62:2787-2790 [23].
G., Fundamentals of Materials Science and Engineering, John Wiley & Sons, third edition, 2007 [25].
Online since: October 2010
Authors: Daniela Herman, Tomasz Okupski, Wiesław Walkowiak
The crystallisation mechanism of glass-ceramic materials from a CMAS group Al0.37B0.34Fe0.01Mg0.02Zn0.29Ca0.05Si0.78O3 was tested under non-isothermal conditions by the DTA method.
By proper selection of chemical composition to obtain specified crystalline phases it was possible to deign materials for specific applications, e.g. body stubs in microelectronics, biomaterials, composite fillers, bonding materials, high-duty and hard materials resistant to wear [1,2].
Glass-ceramic materials from a CMAS group, with the main phase in the form of diopside, respecting their high wear resistance were also used to reinforce among others alumina composites, and also they constituted an important group of materials such as binders for porous abrasive composites [6].
Krzos: Influence of vitrified bond structure on radial wear of cBN grinding wheel, Journal of Materials Processing Technology, 209 (2009), 5377-5386
Choi: Controlled nucleation and crystallization in Fe2O3-CaO-SiO2 glass, Journal of Materials Science 32 (1997) 431-436
By proper selection of chemical composition to obtain specified crystalline phases it was possible to deign materials for specific applications, e.g. body stubs in microelectronics, biomaterials, composite fillers, bonding materials, high-duty and hard materials resistant to wear [1,2].
Glass-ceramic materials from a CMAS group, with the main phase in the form of diopside, respecting their high wear resistance were also used to reinforce among others alumina composites, and also they constituted an important group of materials such as binders for porous abrasive composites [6].
Krzos: Influence of vitrified bond structure on radial wear of cBN grinding wheel, Journal of Materials Processing Technology, 209 (2009), 5377-5386
Choi: Controlled nucleation and crystallization in Fe2O3-CaO-SiO2 glass, Journal of Materials Science 32 (1997) 431-436
Online since: January 2012
Authors: Yong Qiang He, Hua Bin Chen, Xiao Dong Wang, Jian Ping Gao, Hong Sun
Introduction
Soft materials, such as hydrogels, are important materials in the human body.
Soft materials can act as mechanical actuators that convert external stimuli to mechanical energy.
Acknowledgments This work was supported by the National Science Foundation of China (No. 21074089) and Tianjin Municipal Science and Technology Commission, P R China (No. 09JCZDJC23300) References [1] S.V.Ahir and E.M.Terentjev: Nature Materials Vol. 4(2005), p. 491-495
Yao: Journal of Materials Chemistry Vol. 20(2010), p. 9032-9036
[12] C.Park, J.H.Kang, J.S.Harrison et al: Advanced Materials Vol. 20(2008), p. 2074-2079
Soft materials can act as mechanical actuators that convert external stimuli to mechanical energy.
Acknowledgments This work was supported by the National Science Foundation of China (No. 21074089) and Tianjin Municipal Science and Technology Commission, P R China (No. 09JCZDJC23300) References [1] S.V.Ahir and E.M.Terentjev: Nature Materials Vol. 4(2005), p. 491-495
Yao: Journal of Materials Chemistry Vol. 20(2010), p. 9032-9036
[12] C.Park, J.H.Kang, J.S.Harrison et al: Advanced Materials Vol. 20(2008), p. 2074-2079
Online since: February 2026
Authors: Olurotimi Akintunde Dahunsi, Adebisi Olayinka Akinola, Olabisi David Solomon, Temidayo James Akinboye, Gideon Kehinde Oluwaniyi
Materials and Methods
2.1 Translational Motion (Longitudinal Dynamics).
International Journal of Science and Research (IJSR). 8. 7. (2019). 10.21275/ART20203025
Materials Science and Engineering: An Introduction (10th ed.).
Engineering Science and Technology, an International Journal, 24(5), (2021)1290–1300
Journal of Thermal and Fluid Science. 3. 10.26706/jtfs.3.2.20221203
International Journal of Science and Research (IJSR). 8. 7. (2019). 10.21275/ART20203025
Materials Science and Engineering: An Introduction (10th ed.).
Engineering Science and Technology, an International Journal, 24(5), (2021)1290–1300
Journal of Thermal and Fluid Science. 3. 10.26706/jtfs.3.2.20221203
Online since: February 2011
Authors: Shi Ming Hao, Hui Fang Wang, Ren Hong Yu, Yu Bao Bi
Effect of Nanosized Al2O3 as Additive on the Sintering Characteristics and Vickers Hardness of Al2O3/Si3N4 Compound Ceramics
Huifang Wang1, a, Shiming Hao2, b Yubao Bi1,c,Renhong Yu1
1 High Temperature Materials Institute, Henan University of science and technology, Luoyang Henan P.
Experimental procedure Starting materials.
Zhou: Materials Science and Engineering A, Vol431 (2006), P.285 [2] C.
Silva : International Journal of Refractory Metals & Hard Materials ,Vol23 (2005),P. 183–192 [3] Thanakorn Wasanapiarnpong, Shigetaka Wada, Masamitsu Imai, Toyohiko Yano: Journal of the European Ceramic Society,Vol 26 (2006), P. 3467 [4].EN ISO 6507-1:2005 [5] M.T.
Shi: Materials Science and Engineering A,Vol351 (2003), P.9 [6] Tadeusz von Rymon Lipinski. in: Proc. of Unified International Technical Conf. on Refractories (UNITECR’2009), Salvador, Brazil, (2009)
Experimental procedure Starting materials.
Zhou: Materials Science and Engineering A, Vol431 (2006), P.285 [2] C.
Silva : International Journal of Refractory Metals & Hard Materials ,Vol23 (2005),P. 183–192 [3] Thanakorn Wasanapiarnpong, Shigetaka Wada, Masamitsu Imai, Toyohiko Yano: Journal of the European Ceramic Society,Vol 26 (2006), P. 3467 [4].EN ISO 6507-1:2005 [5] M.T.
Shi: Materials Science and Engineering A,Vol351 (2003), P.9 [6] Tadeusz von Rymon Lipinski. in: Proc. of Unified International Technical Conf. on Refractories (UNITECR’2009), Salvador, Brazil, (2009)
Online since: December 2024
Authors: Shun Yong Zhang, Yan Dan Chen, Ya Hui Shi, Ji Cheng Li, Xi Cheng Huang
Geometric modeling of the representative zone, (a1-a3) is materials with VV = 30%, and (b1-b3) is materials with VV = 60%.
Material parameters for different materials.
Effective stress cloud within various materials at a press-in of 600 nm.
References [1] Pan X, Jia C, Ji Z, and Qiu C 2023 Microstructural evolution and dynamic recrystallization mechanism of a heavily-alloyed Ni-based superalloy during hot extrusion Journal of Materials Research and Technology 23 4922-37 [2] Li D, Liu J, Sun Y, Huang W-Q, Li N, and Yang L 2023 Microstructure and mechanical degradation of K403 Ni-based superalloy from ultra-long-term serviced turbine blade Journal of Alloys and Compounds 957 170378 [3] Xu J, Zhao X, Li W, Liu H, Yue Q, Duan H, Gu Y and Zhang Z 2023 Aging process design based on the morphological evolution of γ′ precipitates in a 4th generation nickel-based single crystal superalloy Journal of Materials Science & Technology 147 176-88 [4] Li B, Zhang S, Essa F A, Dong C, Yu J and Zhang Q 2018 Crack Propagation and Microstructural Evolution of Ni-based Single Crystal Alloy Under Shear Loads Rare Metal Materials and Engineering 47 1370-6 [5] Jiang Y, Yue H, Li Q, Ding G, and Wang X 2023 Study on the Machinability of Ni-Based
Superalloy by Milling Parameters and Cooling Methods under Minimal Quantity Lubrication Applied Sciences 13 2773 [6] Zhang S Y, Zhao J F, Liang Y X, Li J C, and Huang X C 2024 Degradation and anisotropy characteristics of fracture toughness in Ni-based superalloys after phase coarsening Materials Science and Engineering: A 889 145852
Material parameters for different materials.
Effective stress cloud within various materials at a press-in of 600 nm.
References [1] Pan X, Jia C, Ji Z, and Qiu C 2023 Microstructural evolution and dynamic recrystallization mechanism of a heavily-alloyed Ni-based superalloy during hot extrusion Journal of Materials Research and Technology 23 4922-37 [2] Li D, Liu J, Sun Y, Huang W-Q, Li N, and Yang L 2023 Microstructure and mechanical degradation of K403 Ni-based superalloy from ultra-long-term serviced turbine blade Journal of Alloys and Compounds 957 170378 [3] Xu J, Zhao X, Li W, Liu H, Yue Q, Duan H, Gu Y and Zhang Z 2023 Aging process design based on the morphological evolution of γ′ precipitates in a 4th generation nickel-based single crystal superalloy Journal of Materials Science & Technology 147 176-88 [4] Li B, Zhang S, Essa F A, Dong C, Yu J and Zhang Q 2018 Crack Propagation and Microstructural Evolution of Ni-based Single Crystal Alloy Under Shear Loads Rare Metal Materials and Engineering 47 1370-6 [5] Jiang Y, Yue H, Li Q, Ding G, and Wang X 2023 Study on the Machinability of Ni-Based
Superalloy by Milling Parameters and Cooling Methods under Minimal Quantity Lubrication Applied Sciences 13 2773 [6] Zhang S Y, Zhao J F, Liang Y X, Li J C, and Huang X C 2024 Degradation and anisotropy characteristics of fracture toughness in Ni-based superalloys after phase coarsening Materials Science and Engineering: A 889 145852