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Online since: June 2005
Authors: Akira Kohyama, Zuhair S. Khan, Tatsuya Hinoki
SiC-composites are candidate structural materials for high temperature applications such
as gas turbines.
The barrier materials were surface coated on the substrates by plasma spray method.
Journal of the European Ceramics Society 22 (2002), p. 2741-2747
Current Opinion in Solid State and Materials Science 5 (2001), p.301-309
Journal of Materials Science Letters 21, 2002, p.121-124
The barrier materials were surface coated on the substrates by plasma spray method.
Journal of the European Ceramics Society 22 (2002), p. 2741-2747
Current Opinion in Solid State and Materials Science 5 (2001), p.301-309
Journal of Materials Science Letters 21, 2002, p.121-124
Online since: August 2023
Authors: Rossen Radev, Danail Gospodinov, Ivo Draganov, Nikolay Ferdinandov
Materials Science and Engineering 564 (2019), pp 1-9
Materials and Design 55 (2014), pp 619-632
Materials Science and Engineering A 405 (2005), pp 333-338
Materials Science and Engineering A 419 (2006), pp 389-396
Journal of Material Processing Technology 203 (2008), pp 411-419
Materials and Design 55 (2014), pp 619-632
Materials Science and Engineering A 405 (2005), pp 333-338
Materials Science and Engineering A 419 (2006), pp 389-396
Journal of Material Processing Technology 203 (2008), pp 411-419
Online since: November 2010
Authors: Ming Gu, Ye Han, Shu Yu Yao, Wei Wei Zhang
Introduction
Composites containing dispersed hard magnetic particles in a glass matrix are important materials for developing compact glass ceramic and glass coated magnetic particles with application in the field of material science and biotechnology[1-3].
[2] Rezlescu, L., et al.: Journal of Magnetism and Magnetic Materials Vol. 193 (1999), p. 288-290
Shim: Journal of Magnetism and Magnetic Materials Vol. 239 (2002), p. 533-536
[4] Han Ye, S.Q., Cao Gao-hui: Journal of Shandong University of Science and Technology Vol. 25 (2006), p. 78-80
-w., Sun Hai-qing, Yao Shu-yu: Journal of Shandong University of Science and Technology Vol. 29 (2001), p. 81-84
[2] Rezlescu, L., et al.: Journal of Magnetism and Magnetic Materials Vol. 193 (1999), p. 288-290
Shim: Journal of Magnetism and Magnetic Materials Vol. 239 (2002), p. 533-536
[4] Han Ye, S.Q., Cao Gao-hui: Journal of Shandong University of Science and Technology Vol. 25 (2006), p. 78-80
-w., Sun Hai-qing, Yao Shu-yu: Journal of Shandong University of Science and Technology Vol. 29 (2001), p. 81-84
Online since: November 2014
Authors: Zhao Yang Zeng, Heng Liu, Yi Min Guo
Introduction
Two targets exist in the microwave absorbing research: one target is looking for new materials with special high permittivity and permeability, the other is focus on the best way to use the presently available microwave absorbing materials.
In the point of materials, most existing materials are not good enough because the matching property is unsatisfactory.
The reason for this is these materials are either electric loss or magnetic loss.
Effective Medium Almost all microwave absorbing samples are made of composite materials: the matrix material usually is polymer, while the reinforce is microwave absorber.
Liu: Journal of Alloys and Compounds Vol.234 (2006), p.1429–1433.
In the point of materials, most existing materials are not good enough because the matching property is unsatisfactory.
The reason for this is these materials are either electric loss or magnetic loss.
Effective Medium Almost all microwave absorbing samples are made of composite materials: the matrix material usually is polymer, while the reinforce is microwave absorber.
Liu: Journal of Alloys and Compounds Vol.234 (2006), p.1429–1433.
Online since: May 2014
Authors: F. García-Vázquez, A. Aguirre, B. Vargas-Arista, H.M. Hernández-García, E.E. Granda-Gutiérrez
Meskinis, Influence of plasma transferred arc process parameters on structure and mechanical properties of wear resistive NiCrBSi-WC/Co coatings, Materials Science 17 (2011) 140-144
Khaira, Improvement in high stress abrasive wear property of steel by hardfacing, Journal of Materials Engineering and Performance 8 (1999) 711-715
Kempulraj, A novel procedure for fabrication ofwear-resistant bushes for high-temperature application, Journal of Materials Processing Technology 141 (2003) 60-66
Santos, Pulsed current plasma transferred arc hardfacing, Journal of Materials Processing Technology 171 (2006) 167–174
Hernández, Analysis of weld bead parameters of overlay deposited on D2 steel components by plasma transferred arc (PTA) process, Materials Science Forum 755 (2013) 39-45.
Khaira, Improvement in high stress abrasive wear property of steel by hardfacing, Journal of Materials Engineering and Performance 8 (1999) 711-715
Kempulraj, A novel procedure for fabrication ofwear-resistant bushes for high-temperature application, Journal of Materials Processing Technology 141 (2003) 60-66
Santos, Pulsed current plasma transferred arc hardfacing, Journal of Materials Processing Technology 171 (2006) 167–174
Hernández, Analysis of weld bead parameters of overlay deposited on D2 steel components by plasma transferred arc (PTA) process, Materials Science Forum 755 (2013) 39-45.
Online since: June 2019
Authors: Yi Qiang He, Chang Xu Ren, Hu Lin Xu
Journal of Materials Engineering and Performance, 2011, 20(2):238-243
Journal of Materials Engineering and Performance, 2014, 23(4): 1440-1450
Materials Science and Engineering, 2007, A460-461: 180-185
Advanced Composite Materials, 2009, 18(4): 339-350
Advanced Composite Materials, 2013, 22(4): 227-237
Journal of Materials Engineering and Performance, 2014, 23(4): 1440-1450
Materials Science and Engineering, 2007, A460-461: 180-185
Advanced Composite Materials, 2009, 18(4): 339-350
Advanced Composite Materials, 2013, 22(4): 227-237
Online since: November 2007
Authors: Mohan J. Edirisinghe, Serena Best, Z. Ahmad, J.H. Robinson
With limited supplies of autograft material and the immune
reactions associated with allograft material there is a clear demand for synthetic graft materials.
References 1.Pompe, W., Worch, H., Epple, M., Friess, W., Gelinsky, M., Greil, P., Hempel, D., Scharnweber, D., and Schulte, K., Materials Science and Engineering A,(2003). 362: p. 40-60. 2.Rodríguez-Lorenzo, L.M. and Ferreira, J.M.F., Materials Research Bulletin,(2004). 39: p. 83-91. 3.Jinawath, S., Polchai, D., and Yoshimura, M., Materials Science and Engineering C,(2002). 22: p. 35-39. 4.Rocha, J.H.G., Lemos, A.F., Agathopoulos, S., Valerio, P., Kannan, S., Oktar, F.N., and Ferreira, J.M.F., Bone,(2005). 37(6): p. 850-857. 5.Tamai, N., Myoui, A., Tomita, T., Nakase, T., Tanaka, J., Ochi, T., and Yoshikawa, H., Journal of Biomedical Materials Research,(2001). 59: p. 110-117. 6.Tian, J. and Tian, J., Journal of Materials Science,(2001). 36: p. 3061-3066. 7.Kim, H.
-E., Journal of Biomedical Materials Research, Part B: Applied Biomaterials.,(2004). 70B: p. 240-249. 9.Chu, T.
-M.G., Halloran, J.W., Hollister, S.J., and Feinberg, S.E., Journal of Materials Science: Materials in Medicine,(2001). 12: p. 471-478. 10.Woez, A., Rumpler, M., Stampfl, J., Varga, F., Fratzl-Zelman, N., Roschger, P., Klaushofer, K., and Fratzl, P., Materials Science and Engineering C,(2005). 25: p. 181-186. 11.Bouyer, E., Gitzhofer, F., and Boulos, M.I., Journal of Materials Science: Materials in Medicine,(2000). 11(8): p. 523-531. 12.Lazic, S., Zec, S., Miljevic, N., and Milonjic, S., Thermochimica Acta,(2001). 374(1): p. 13-22. 13.J.
Barralet, S.B.W.B., Journal of Biomedical Materials Research,(1998). 41(1): p. 79-86. 14.Luyten, J., Thijs, I., Vandermeulen, W., Mullens, S., Wallaeys, B., and Mortelmans, R., Advances in Applied Ceramics,(2005). 104: p. 4-8. 15.Mobasherpour, I., Heshajin, M.S., Kazemzadeh, A., and Zakeri, M., Journal of Alloys and Compounds,(2007). 430(1-2): p. 330-333. 16.Bamford, C.H. and Al-Lamee, K.G., Polymer,(1994). 35(13): p. 2844-2852.
References 1.Pompe, W., Worch, H., Epple, M., Friess, W., Gelinsky, M., Greil, P., Hempel, D., Scharnweber, D., and Schulte, K., Materials Science and Engineering A,(2003). 362: p. 40-60. 2.Rodríguez-Lorenzo, L.M. and Ferreira, J.M.F., Materials Research Bulletin,(2004). 39: p. 83-91. 3.Jinawath, S., Polchai, D., and Yoshimura, M., Materials Science and Engineering C,(2002). 22: p. 35-39. 4.Rocha, J.H.G., Lemos, A.F., Agathopoulos, S., Valerio, P., Kannan, S., Oktar, F.N., and Ferreira, J.M.F., Bone,(2005). 37(6): p. 850-857. 5.Tamai, N., Myoui, A., Tomita, T., Nakase, T., Tanaka, J., Ochi, T., and Yoshikawa, H., Journal of Biomedical Materials Research,(2001). 59: p. 110-117. 6.Tian, J. and Tian, J., Journal of Materials Science,(2001). 36: p. 3061-3066. 7.Kim, H.
-E., Journal of Biomedical Materials Research, Part B: Applied Biomaterials.,(2004). 70B: p. 240-249. 9.Chu, T.
-M.G., Halloran, J.W., Hollister, S.J., and Feinberg, S.E., Journal of Materials Science: Materials in Medicine,(2001). 12: p. 471-478. 10.Woez, A., Rumpler, M., Stampfl, J., Varga, F., Fratzl-Zelman, N., Roschger, P., Klaushofer, K., and Fratzl, P., Materials Science and Engineering C,(2005). 25: p. 181-186. 11.Bouyer, E., Gitzhofer, F., and Boulos, M.I., Journal of Materials Science: Materials in Medicine,(2000). 11(8): p. 523-531. 12.Lazic, S., Zec, S., Miljevic, N., and Milonjic, S., Thermochimica Acta,(2001). 374(1): p. 13-22. 13.J.
Barralet, S.B.W.B., Journal of Biomedical Materials Research,(1998). 41(1): p. 79-86. 14.Luyten, J., Thijs, I., Vandermeulen, W., Mullens, S., Wallaeys, B., and Mortelmans, R., Advances in Applied Ceramics,(2005). 104: p. 4-8. 15.Mobasherpour, I., Heshajin, M.S., Kazemzadeh, A., and Zakeri, M., Journal of Alloys and Compounds,(2007). 430(1-2): p. 330-333. 16.Bamford, C.H. and Al-Lamee, K.G., Polymer,(1994). 35(13): p. 2844-2852.
Online since: June 2014
Authors: Miguel Ángel Sebastián, Lorenzo Sevilla Hurtado, Ana M. Camacho, Francisco de Sales Martín Fernández
Mechanical Journal of Science and Technology, 23 (2009) 461-474
Materials Science Forum, 713 (2012) 13-18
Journal of Materials Processing Technology, 79 (1998) 14-24
Journal of Achievements in Materials and Manufacturing Engineering, 15 (2006) 166-173
Materials and Manufacturing Processes.
Materials Science Forum, 713 (2012) 13-18
Journal of Materials Processing Technology, 79 (1998) 14-24
Journal of Achievements in Materials and Manufacturing Engineering, 15 (2006) 166-173
Materials and Manufacturing Processes.
Online since: July 2020
Authors: Mohd Sabri Mohd Ghazali, Wan Rafizah Wan Abdullah, Noradhiha Farahin Ibrahim, Maishara Syazrinni Rooshde, Amie Zaidah Amran, Fazilah Ariffin
amysara.rinni@gmail.com, b*wanrafizah@umt.edu.my, camyaida94@gmail.com dadhiha.ibrahim@gmail.com, efazilah@umt.edu.my and fmohdsabri@umt.edu.my,
Keywords: Ce doped ZnO, photocatalytic treatment, E. coli, S. aureus, antifouling, rare earth materials
Abstract.
Therefore, a novel antifouling based materials with the incorporation of nanotechnology has been developed for the prevention of biofouling in its initial stage through photocatalytic treatment.
In addition to that, very limited works reported the efficiency of these catalytic materials for removal of microbial pollutants or antifouling agent.
Kim, Inverted polymer solar cells with brush-painted ZnO electron transport layer, Journal of industrial and engineering chemistry. 59 (2018) 335-340
Ursu, New insights into structural and magnetic properties of Ce doped ZnO nanoparticles, Journal of Alloys and Compounds. 757 (2018) 60-69
Therefore, a novel antifouling based materials with the incorporation of nanotechnology has been developed for the prevention of biofouling in its initial stage through photocatalytic treatment.
In addition to that, very limited works reported the efficiency of these catalytic materials for removal of microbial pollutants or antifouling agent.
Kim, Inverted polymer solar cells with brush-painted ZnO electron transport layer, Journal of industrial and engineering chemistry. 59 (2018) 335-340
Ursu, New insights into structural and magnetic properties of Ce doped ZnO nanoparticles, Journal of Alloys and Compounds. 757 (2018) 60-69
Online since: December 2024
Authors: Nasrullah Idris, Eka Safitri, Faridah Hanum, Rinaldi Idroes
The process of synthesizing polyurethane (PU) membranes typically involves linking together networks of polymers using organic materials like polyols and isocyanates.
The choice between organic and inorganic materials is contingent upon the specific requirements of the application and the intended characteristics of the PU membrane [2].
The composition of the materials employed in the synthesis procedure of the PU membrane plays a crucial role in governing the production of the hard and soft segments within the membrane structure.
Experimental The materials used were ĸ-carrageenan powder, di(2-ethylhexyl)phosphoric acid (D2EHPA) (Merck), acetone, and toluene diisocyanate (TDI) as a reagent in pro's quality analysis from Merck (Darmstadt, Germany).
Cardenas-Lopez, J.Lopez-Elias et al, Saudi Journal of Biological Sciences 28, 1401-1416 (2021)
The choice between organic and inorganic materials is contingent upon the specific requirements of the application and the intended characteristics of the PU membrane [2].
The composition of the materials employed in the synthesis procedure of the PU membrane plays a crucial role in governing the production of the hard and soft segments within the membrane structure.
Experimental The materials used were ĸ-carrageenan powder, di(2-ethylhexyl)phosphoric acid (D2EHPA) (Merck), acetone, and toluene diisocyanate (TDI) as a reagent in pro's quality analysis from Merck (Darmstadt, Germany).
Cardenas-Lopez, J.Lopez-Elias et al, Saudi Journal of Biological Sciences 28, 1401-1416 (2021)