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Fabrication and Growth Mechanism of Nanoleaf Sodium Titanate Coating on High-Purity Titanium Surface
Online since: August 2018
Authors: Akiyoshi Osaka, Yan Fu Yan, Ya Ming Wang, Zhi Lu, Guang Xin Wang, Shuai Dong Guo, Shun Lan Deng, Yong Fa Song
China
2Research Center for High Purity Materials, Henan University of Science and Technology, Luoyang, Henan, 471023, P.R.
It is well known that sodium titanate and its derivatives are excellent conductive and sensing materials.
Elkhooly, Preparation and characterization of TiO2 /silicate hierarchical coating on titanium surface for biomedical applications, Materials Science and Engineering C. 60 (2016) 308-316
Kim, A mini-review: cell response to microscale, nanoscale, and hierarchical patterning of surface structure, Journal of Biomedical Materials Research Part B Applied Biomaterials. 102 (2014) 1580-1594
Zhang, Effects of growth substrate on the morphologies of TiO2 hierarchical nanoarrays and their optical and photocatalytic properties, Journal of Materials Science Materials in Electronics. 27 (2016) 2103-2107
It is well known that sodium titanate and its derivatives are excellent conductive and sensing materials.
Elkhooly, Preparation and characterization of TiO2 /silicate hierarchical coating on titanium surface for biomedical applications, Materials Science and Engineering C. 60 (2016) 308-316
Kim, A mini-review: cell response to microscale, nanoscale, and hierarchical patterning of surface structure, Journal of Biomedical Materials Research Part B Applied Biomaterials. 102 (2014) 1580-1594
Zhang, Effects of growth substrate on the morphologies of TiO2 hierarchical nanoarrays and their optical and photocatalytic properties, Journal of Materials Science Materials in Electronics. 27 (2016) 2103-2107
Online since: April 2014
Authors: Petra Lacková, Ondrej Milkovič, Daniela Žabecká, Milan Škrobian, Matúš Bajcura
Fatigue damage makes 75% of all damages of the construction materials [4].
In Journal of Aeronautical Materials, 2009, 29(1), pp.96-100
In Engineering Materials, 2011, pp. 13-16
In Engineering Materials, 2012, pp. 45-48
Metallic materials – Tensile testing.
In Journal of Aeronautical Materials, 2009, 29(1), pp.96-100
In Engineering Materials, 2011, pp. 13-16
In Engineering Materials, 2012, pp. 45-48
Metallic materials – Tensile testing.
Online since: August 2021
Authors: R. Suganthini Rekha, S. Nallusamy, M. Rajaram Narayanan, K. Sujatha
Mechanical properties were investigated on multiphase materials applied a generalized means to distinguish the elastic modulus of is the bulk, shear and young's modulus with strength of flow for multistage composite material [4-6].
[4] Han, Q., Chen, P and Ma, T., Influencing factor analysis of shale micro-indentation measurement, Journal of Natural Gas Science and Engineering. 27 (2015) 641-650
Beecham, The relationship between porosity and strength for porous concrete, Construction and Building Materials. 25(11) (2011) 4294-4298
[10] Baud, Wong, T.F and Zhu, W, Effects of porosity and crack density on the compressive strength of rocks, International Journal of Rock Mechanics and Mining Sciences. 67 (2014) 202-211
[16] Medani, Mohammed et al., Static and dynamic behavior of (FG-CNT) reinforced porous sandwich plate using energy principle, Steel and Composite Structures. 32(5) (2019) 595-610 [17] Liu et al, Dynamic mechanical behaviour of recycled crumb rubber concrete materials subjected to repeated impact, Journal of Materials Research Innovations. 19(8) (2015) 496-501 [18] Nikhilesh and Chawla, Microstructure-based modeling of the deformation behavior of particle reinforced metal matrix composites, Journal of Materials Science. 41(3) (2016) 913-925
[4] Han, Q., Chen, P and Ma, T., Influencing factor analysis of shale micro-indentation measurement, Journal of Natural Gas Science and Engineering. 27 (2015) 641-650
Beecham, The relationship between porosity and strength for porous concrete, Construction and Building Materials. 25(11) (2011) 4294-4298
[10] Baud, Wong, T.F and Zhu, W, Effects of porosity and crack density on the compressive strength of rocks, International Journal of Rock Mechanics and Mining Sciences. 67 (2014) 202-211
[16] Medani, Mohammed et al., Static and dynamic behavior of (FG-CNT) reinforced porous sandwich plate using energy principle, Steel and Composite Structures. 32(5) (2019) 595-610 [17] Liu et al, Dynamic mechanical behaviour of recycled crumb rubber concrete materials subjected to repeated impact, Journal of Materials Research Innovations. 19(8) (2015) 496-501 [18] Nikhilesh and Chawla, Microstructure-based modeling of the deformation behavior of particle reinforced metal matrix composites, Journal of Materials Science. 41(3) (2016) 913-925
Online since: January 2019
Authors: Wen Tong Tian, Hui Yang
The purpose of the paper is to improve the traditional mechanical stirring method, which may be of fundamental knowledge for developing advanced semi-solid forming process.
1 Experimental Procedure
1.1 Experimental Materials
The alloy used in the present study was A356 ingot.
Brabazon, The effect of direct thermal method, temperature and time on microstructure of a cast aluminum alloy, Materials and Manufacturing Process. 29 (2014) 134-139
[3] Sahrooz Nafisi, Reza Ghomashchi, Impact of melt treatment on semi-solid metal processing, Journal of Alloys and Compounds. 436 (2007) 86-90
Julathep, Metallurgical structure of A356 aluminum alloy solidified under mechanical vibration: An investigation of alternative semi-solid casting routes, Materials and Design. 30 (2009) 3925-3930
T Ramesh, Strengthening mechanisms in an Al-Mg alloy, Materials Science and Engineering:A. 527(6) (2014) 1292-1298
Brabazon, The effect of direct thermal method, temperature and time on microstructure of a cast aluminum alloy, Materials and Manufacturing Process. 29 (2014) 134-139
[3] Sahrooz Nafisi, Reza Ghomashchi, Impact of melt treatment on semi-solid metal processing, Journal of Alloys and Compounds. 436 (2007) 86-90
Julathep, Metallurgical structure of A356 aluminum alloy solidified under mechanical vibration: An investigation of alternative semi-solid casting routes, Materials and Design. 30 (2009) 3925-3930
T Ramesh, Strengthening mechanisms in an Al-Mg alloy, Materials Science and Engineering:A. 527(6) (2014) 1292-1298
Online since: August 2018
Authors: Tadashi Nishihara, Tetta Tajima, Hamed Mofidi Tabatabaei
Introduction
Composite materials have wide applications in cutting-edge ranges of advanced materials as medical devices, sport parts, automotive and especially for materials that are needed for aerospace, underwater, and transportation applications.
Callister, Jr., Materials Science and Engineering.
Olson, Application of Soft Magnetic Materials and Specialty Alloys, Journal of Applied Physics. 37 (1966) 1197-1201
Nishihara, Production of a Superplastic Vibration-Damping Steel Sheet Composite using Friction Stir Forming, Materials Science Forum. 838-839 (2016) 574-580
[7] Hamed Mofidi Tabatabaei, Tadashi Nishihara, Friction Stir Forming for Mechanical Interlocking of Insulated Copper Wire and Zn-22Al Superplastic Alloy, Welding in the World (The International Journal of Materials Joining). 61, Issue 1 (2017) 44-55
Callister, Jr., Materials Science and Engineering.
Olson, Application of Soft Magnetic Materials and Specialty Alloys, Journal of Applied Physics. 37 (1966) 1197-1201
Nishihara, Production of a Superplastic Vibration-Damping Steel Sheet Composite using Friction Stir Forming, Materials Science Forum. 838-839 (2016) 574-580
[7] Hamed Mofidi Tabatabaei, Tadashi Nishihara, Friction Stir Forming for Mechanical Interlocking of Insulated Copper Wire and Zn-22Al Superplastic Alloy, Welding in the World (The International Journal of Materials Joining). 61, Issue 1 (2017) 44-55
Online since: April 2018
Authors: Ryan C. McCuiston, Wanida Nonthathi, Chiraporn Auechalitanukul
Bottom ash is a waste byproduct generated from the combustion or incineration of materials such as coal and household waste.
Bottom ashes generated from the incineration of municipal solid waste (MSW) are a mix of inert materials, such as sand, stone, glass, porcelain, metals and ashes from the burnt materials.
The high Al2O3 content on many bottom ashes can result in low cost materials that are corrosion and abrasion resistant.
We would also like to thank the Department of Materials Science, Faculty of Science, Srinakharinwirot University, and Department of Physics and Materials Science, Faculty of Science, Chiang Mai University for providing access to their research facilities.
-H., 2008, “Recycling MSWI bottom and fly ash as raw materials for Portland cement”, Waste Management, vol. 28, pp. 1113–1118
Bottom ashes generated from the incineration of municipal solid waste (MSW) are a mix of inert materials, such as sand, stone, glass, porcelain, metals and ashes from the burnt materials.
The high Al2O3 content on many bottom ashes can result in low cost materials that are corrosion and abrasion resistant.
We would also like to thank the Department of Materials Science, Faculty of Science, Srinakharinwirot University, and Department of Physics and Materials Science, Faculty of Science, Chiang Mai University for providing access to their research facilities.
-H., 2008, “Recycling MSWI bottom and fly ash as raw materials for Portland cement”, Waste Management, vol. 28, pp. 1113–1118
Online since: May 2006
Authors: Jorge M. Silva, Ana Vera Machado, João M. Maia
The rheological properties of compatibilized polymer
blends, namely on the understanding of how compatibilizers change the interfacial proprieties and,
consequently, the rheological behaviour of the materials is a very important issue about which there
are relatively few studies available.
Materials and methods Several blends of a commercial polyamide-6 (PA-6 Akulon® K123), an ethene-propene rubber (EPM Keltan® 740) and an ethene-propene rubber modified with maleic anhydride (EPM-g-MA ExxelorVA 1801, containing 0.49 wt% of MA, as determined by FT-IR) were prepared in a twin screw extruder, under the same process conditions.
Sirivat et al.: Polymer Engineering and Science Vol. 42 (2002), p. 798 [7] W.
Covas et al.: Journal of Polymer Science Part a-Polymer Chemistry Vol. 37 (1999), p. 1311 [12] L.
Utracki: Polymer Engineering Science Vol. 23 (1983), p. 602
Materials and methods Several blends of a commercial polyamide-6 (PA-6 Akulon® K123), an ethene-propene rubber (EPM Keltan® 740) and an ethene-propene rubber modified with maleic anhydride (EPM-g-MA ExxelorVA 1801, containing 0.49 wt% of MA, as determined by FT-IR) were prepared in a twin screw extruder, under the same process conditions.
Sirivat et al.: Polymer Engineering and Science Vol. 42 (2002), p. 798 [7] W.
Covas et al.: Journal of Polymer Science Part a-Polymer Chemistry Vol. 37 (1999), p. 1311 [12] L.
Utracki: Polymer Engineering Science Vol. 23 (1983), p. 602
Online since: November 2010
Authors: Qing Xi Hou, Yong Gang Yang, Shu Hua Hu
[3] Grace J: Journal of Pulp and Paper Science,1993,19(5):208-213
[4] Pauler N,Bristow J: Nordic Pulp and Paper Research Journal,1994,9(4):226-231
[8] Chinga G,Eilertsen M: Journal of Pulp and Paper Science,2007,33 (3):125-132
[14] Mäkinen M,Happonen J,Sahivirta J,et al: Journal of Pulp and Paper Science,2007,33(1):35-43
Printing Materials and its Printability[M].Beijing:Printing Industry Press,2000
[4] Pauler N,Bristow J: Nordic Pulp and Paper Research Journal,1994,9(4):226-231
[8] Chinga G,Eilertsen M: Journal of Pulp and Paper Science,2007,33 (3):125-132
[14] Mäkinen M,Happonen J,Sahivirta J,et al: Journal of Pulp and Paper Science,2007,33(1):35-43
Printing Materials and its Printability[M].Beijing:Printing Industry Press,2000
Online since: December 2014
Authors: Daniel Rodrigues, Marcos Flavio de Campos, Célio de Jesus Marcelo, Kaio Sérgio Torres de Souza, José Adilson de Castro
Chen: Journal of Magnetism and Magnetic Materials Vol. 48 (2002), p. 432
[5].M.F. de Campos: Materials Science Forum Vol. 660-661 (2010), p. 284
Hulda: Materials Science Forum Vol. 467-470 (2004), p. 985
Ferrante: Journal of Materials Synthesis and Processing.
Rodrigues, M.F. de Campos: Materials Science Forum Vols. 727-728 (2012), p. 440
[5].M.F. de Campos: Materials Science Forum Vol. 660-661 (2010), p. 284
Hulda: Materials Science Forum Vol. 467-470 (2004), p. 985
Ferrante: Journal of Materials Synthesis and Processing.
Rodrigues, M.F. de Campos: Materials Science Forum Vols. 727-728 (2012), p. 440
Online since: October 2022
Authors: Mikelis Kirpluks, Arnis Abolins, Elīza Kauliņa, Anda Fridrihsone
Tall oils are a second-generation feedstock with perspective use in polyurethane materials.
Bio-polyols can be used in the production of rigid polyurethane (PU) foam thermal insulation materials.
Tall oil can be used as one of the raw materials for bio-polyol production.
Tang, “Sustainable polymers from biomass: Bridging chemistry with materials and processing,” Progress in Polymer Science, vol. 101.
Walterova, “Highly functional polyol synthesis from epoxidized tall oil fatty acids,” Journal of Renewable Materials, vol. 6, no. 7, pp. 764–771, Dec. 2018, doi: 10.7569/JRM.2018.634111
Bio-polyols can be used in the production of rigid polyurethane (PU) foam thermal insulation materials.
Tall oil can be used as one of the raw materials for bio-polyol production.
Tang, “Sustainable polymers from biomass: Bridging chemistry with materials and processing,” Progress in Polymer Science, vol. 101.
Walterova, “Highly functional polyol synthesis from epoxidized tall oil fatty acids,” Journal of Renewable Materials, vol. 6, no. 7, pp. 764–771, Dec. 2018, doi: 10.7569/JRM.2018.634111