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Online since: July 2021
Authors: Nibras Fadhil Ali, Azhar A. Habeeb, Adel H. Omran Alkhayatt
Pandey,Materials Chemistry and Physics, 116, 638–644 (2009)
Fiechter, Journal of Materials Science & Technology, 31, 655-659 (2015(
Naseem, Materials Today: Proceedings, 2, 5415-5420 (2015)
Pech-Canul., Materials Science Forum, 644, 105–108(2010)
Omran.Alkhayatt, Al- Qadisyah Journal for Science, 14(2), 76-88 (2009)
Fiechter, Journal of Materials Science & Technology, 31, 655-659 (2015(
Naseem, Materials Today: Proceedings, 2, 5415-5420 (2015)
Pech-Canul., Materials Science Forum, 644, 105–108(2010)
Omran.Alkhayatt, Al- Qadisyah Journal for Science, 14(2), 76-88 (2009)
Online since: July 2011
Authors: Bai Sheng Nie, Xue Qiu He, Xiang Chun Li, Hui Wang, Sheng Rui Zhai, Ru Ming Zhang
China Safety Science Journal, 2001 (11): 60-64.
Progress in Energy and Combustion Science, 2008 (34):499-550
Journal of Hazardous Materials, 1997 (52):1-150
Combustion Science and Technology, 2006, 178(10-11):1755
Journal of China Coal Society, 2008, 33(8):903-907.
Progress in Energy and Combustion Science, 2008 (34):499-550
Journal of Hazardous Materials, 1997 (52):1-150
Combustion Science and Technology, 2006, 178(10-11):1755
Journal of China Coal Society, 2008, 33(8):903-907.
Online since: March 2020
Authors: Wei Yin, Yan Wang
Plasma has a large number of highly reactive electrons, ions and free radicals, which directly causes the surface modification or polymerization of polymer materials.
The materials used in the experiments are shown in Table 1.
Zhang, The effect of steam explosion treatment on the separation of lotus fiber, In Advanced Materials Research, 750(2013) 2307-2312
Effects of anisotropic pore structure and fiber texture on fatigue properties of lotus-type porous magnesium, Journal of Materials Research,22 (2007) 3120-3129
Zou, Green textile materials and techniques for water resource protection.
The materials used in the experiments are shown in Table 1.
Zhang, The effect of steam explosion treatment on the separation of lotus fiber, In Advanced Materials Research, 750(2013) 2307-2312
Effects of anisotropic pore structure and fiber texture on fatigue properties of lotus-type porous magnesium, Journal of Materials Research,22 (2007) 3120-3129
Zou, Green textile materials and techniques for water resource protection.
Online since: August 2013
Authors: Paulo Bártolo, Margarida C. Franco, Tânia Viana, Sara Biscaia
Materials and Methods
Materials
Very low viscosity sodium alginate (SA) was purchased from Alfa Aesar GmbH & Co.
All the aforementioned materials were used without any change or modification relatively to original supplier.
[4] Kulkarni P., Keshavayya J.: Chitosan-sodium alginate biodegradable interpenetrating polymer network (IPN) beads for delivery of ofloxacin hydrochloride, International Journal of Pharmacy and Pharmaceutical Sciences, 2 (2), pp. 77-82 (2010)
[6] Kulkarni R., Yogesh &, Wagh J.: Crosslinked alginate films as rate controlling membranes for transdermal drug delivery applications, Journal of Macromolecular Science, Part A (2010)
[9] Fwo-Long-Mi Fwu-Long Mi, Hsiang-Fa Liang, Yung-Chih Wu, Yu-Shin Lin, Ting-Fan Yang, Hsing-Wen Sunget: pH-sensitive behavior of two-component hydrogels composed of N,O-carboxymethyl chitosan and alginate, Journal Biomaterials, Science Polymer Edn, Vol. 16, nº 11, pp. 1333-1345 (2005)
All the aforementioned materials were used without any change or modification relatively to original supplier.
[4] Kulkarni P., Keshavayya J.: Chitosan-sodium alginate biodegradable interpenetrating polymer network (IPN) beads for delivery of ofloxacin hydrochloride, International Journal of Pharmacy and Pharmaceutical Sciences, 2 (2), pp. 77-82 (2010)
[6] Kulkarni R., Yogesh &, Wagh J.: Crosslinked alginate films as rate controlling membranes for transdermal drug delivery applications, Journal of Macromolecular Science, Part A (2010)
[9] Fwo-Long-Mi Fwu-Long Mi, Hsiang-Fa Liang, Yung-Chih Wu, Yu-Shin Lin, Ting-Fan Yang, Hsing-Wen Sunget: pH-sensitive behavior of two-component hydrogels composed of N,O-carboxymethyl chitosan and alginate, Journal Biomaterials, Science Polymer Edn, Vol. 16, nº 11, pp. 1333-1345 (2005)
Online since: December 2010
Authors: Norhamidi Muhamad, Sufizar Ahmad, Mohd Halim Irwan Ibrahim, Mohd Ruzi Harun, Nor Hafiez Mohamad Nor
Khor, “Production of Metal Matrix Composite Part by Powder Injection Molding”, Journal of Materials Processing Technology, Vol. 108, (2001) p. 398-407
Journal of Materials Processing Technology, Vol. 71, (1997), p. 337-342
Materials Science and Engineering A, Vol. 311, (2001), p. 74-82
Chiang Mai Journal of Science,Vol. 36, 3, (2009), p. 349-358
Krajnik: Robust Design of Flank Milling Parameters Based On Grey-Taguchi Method, Journal of Materials Processing Technology, Vol.191, (2007), p. 400–403
Journal of Materials Processing Technology, Vol. 71, (1997), p. 337-342
Materials Science and Engineering A, Vol. 311, (2001), p. 74-82
Chiang Mai Journal of Science,Vol. 36, 3, (2009), p. 349-358
Krajnik: Robust Design of Flank Milling Parameters Based On Grey-Taguchi Method, Journal of Materials Processing Technology, Vol.191, (2007), p. 400–403
Online since: January 2025
Authors: Yusuf Şahin
Blue, “ The importance of carbon fiber to polymer additive manufacturing,” Journal of Materials Research, 29 (17) (2014) 1893–1898. https://doi.org/10.1557/jmr.2014.212
Hatakeyama, “Crystallization of carbon fiber reinforced polypropylene,” Journal of Materials Science, 25 (7) (1990) 3380-3384
Series: Materials Science and Engineering, 402 (2018) 012136. https://doi.org/10.1088/1757-899X/402/1/012136
Series: Materials Science and Engineering, 1118 (2021) 012035. https:// doi.org/10.1088/1757-899X/1118/1/012035
Warrior, “Fiber alignment in directed carbon fiber preforms – A feasibility study,” Journal of Composite Materials, 43 (1) (2009) 57-74
Hatakeyama, “Crystallization of carbon fiber reinforced polypropylene,” Journal of Materials Science, 25 (7) (1990) 3380-3384
Series: Materials Science and Engineering, 402 (2018) 012136. https://doi.org/10.1088/1757-899X/402/1/012136
Series: Materials Science and Engineering, 1118 (2021) 012035. https:// doi.org/10.1088/1757-899X/1118/1/012035
Warrior, “Fiber alignment in directed carbon fiber preforms – A feasibility study,” Journal of Composite Materials, 43 (1) (2009) 57-74
Online since: August 2014
Authors: Jian Zhong Cui, Song Lin Huang
Ryu, B.Hong and J.Kwon: Journal of Computer Science and Technology, Vol. 27 (2012) No.1, p.213
King: Journal of Computer Science and Technology,Vol. 22 (2007) No.3, p.438
Guo: Journal of Thermal Science,Vol. 13 (2004) No.4, p.128
Xu: Journal of Systems Science and Systems Engineering, Vol. 22 (2013) No.2, p.152
Li: Journal of Computer Science and Technology, Vol. 24 (2009) No.4, p.723.
King: Journal of Computer Science and Technology,Vol. 22 (2007) No.3, p.438
Guo: Journal of Thermal Science,Vol. 13 (2004) No.4, p.128
Xu: Journal of Systems Science and Systems Engineering, Vol. 22 (2013) No.2, p.152
Li: Journal of Computer Science and Technology, Vol. 24 (2009) No.4, p.723.
Online since: March 2021
Authors: Meng Li, Zhi Xun Wen, Xiao Yan Wang
Journal of Alloys & Compounds, 2017, 692:301-312
Journal of Alloys & Compounds, 2017, 692:301-312
Materials Science Forum, 2014, 783-786:2491-2496
Materials Science and Engineering, 1979, 37(3):237-247
Journal of Materials Engineering and Performance, 1993, 2(5):745-758
Journal of Alloys & Compounds, 2017, 692:301-312
Materials Science Forum, 2014, 783-786:2491-2496
Materials Science and Engineering, 1979, 37(3):237-247
Journal of Materials Engineering and Performance, 1993, 2(5):745-758
Online since: May 2015
Authors: Qian Chen, Mu Chun Yu, Xue Gao
Introduction
In general, nanoporous materials, such as zeolites, are usually utilized in adsorption, separation, ion-exchange heterogeneous catalysis and other desired functions.
Zeolites are microporous crystalline materials with an inorganic, three dimensional host structure comprised of fully linked, corner-sharing tetrahedron.
Fig. 1 Silicalite-1 Fig. 2 Schematic view of molecular spring isolator In present, researches on molecular spring are mainly concentrated on synthesizing new materials [6] or molecular simulations of water adsorption in zeolites [7].
References [1] C.Suciu, T.Iwatsubo: Investigation of a colloidal damper, Journal of Colloidal and Interface Science, Vol. 259, pp. 62-80. (2001) [2] A.Fadeev, V.Eroshenko: Study of penetration of water into hydrophobized porous silicas , Journal of Colloid and Interface Science, Vol.187, pp. 275-282. (1997) [3] M.Trzpit, S.Rigolet and J.Paillaud: Pure silica chabazite molecular spring: a structural study on water intrusion-extrusion processes, Journal of Physical Chemistry,Vol.112, pp.7257-7266. (2008) [4] V.Eroshenko, R.Regis and M.Soulard, et al.: Energetic: a new field of application of hydrophobic zeolites, Journal of The American Chemical Society, Vol.123, pp. 8129-8130. (2001) [5] M.Soulard, J.Patarin and V.Eroshenko, et al.: Molecular spring or bumper: a new application for hydrophobic zeolites materials, Studies in Surface Science and Catalysis, Vol.154, pp. 1830-1837. (2004) [6] L.Tzanis, M.Trzpit and M.Soulard, et al.: High pressure water intrusion investigation of pure
silica 1D channel AFI, MTW and TON-type zeolites, Microporous and Mesoporous Materials, Vol.146, pp. 119-126. (2011) [7] N.Desbiens, A.Boutin and I.Demachy: Water condensation in hydrophobic silicalite-1 zeolite: a molecular simulation study, Journal of Physical Chemistry, Vol.109, pp. 24071-24076. (2005) [8] F.T.Zhang: Fundamentals of Molecular Interface Chemistry, first ed., Shanghai Scientific and Technological Literature Press, Shanghai, 2006
Zeolites are microporous crystalline materials with an inorganic, three dimensional host structure comprised of fully linked, corner-sharing tetrahedron.
Fig. 1 Silicalite-1 Fig. 2 Schematic view of molecular spring isolator In present, researches on molecular spring are mainly concentrated on synthesizing new materials [6] or molecular simulations of water adsorption in zeolites [7].
References [1] C.Suciu, T.Iwatsubo: Investigation of a colloidal damper, Journal of Colloidal and Interface Science, Vol. 259, pp. 62-80. (2001) [2] A.Fadeev, V.Eroshenko: Study of penetration of water into hydrophobized porous silicas , Journal of Colloid and Interface Science, Vol.187, pp. 275-282. (1997) [3] M.Trzpit, S.Rigolet and J.Paillaud: Pure silica chabazite molecular spring: a structural study on water intrusion-extrusion processes, Journal of Physical Chemistry,Vol.112, pp.7257-7266. (2008) [4] V.Eroshenko, R.Regis and M.Soulard, et al.: Energetic: a new field of application of hydrophobic zeolites, Journal of The American Chemical Society, Vol.123, pp. 8129-8130. (2001) [5] M.Soulard, J.Patarin and V.Eroshenko, et al.: Molecular spring or bumper: a new application for hydrophobic zeolites materials, Studies in Surface Science and Catalysis, Vol.154, pp. 1830-1837. (2004) [6] L.Tzanis, M.Trzpit and M.Soulard, et al.: High pressure water intrusion investigation of pure
silica 1D channel AFI, MTW and TON-type zeolites, Microporous and Mesoporous Materials, Vol.146, pp. 119-126. (2011) [7] N.Desbiens, A.Boutin and I.Demachy: Water condensation in hydrophobic silicalite-1 zeolite: a molecular simulation study, Journal of Physical Chemistry, Vol.109, pp. 24071-24076. (2005) [8] F.T.Zhang: Fundamentals of Molecular Interface Chemistry, first ed., Shanghai Scientific and Technological Literature Press, Shanghai, 2006
Online since: April 2021
Authors: Guney Guven Yapici, Amin Radi, Seyed Veghar Seyedmohammadi
Materials Science Forum 887 (2017) 104-107
Van Humbeeck, Shape memory alloys: a material and a technology, Advanced engineering materials 3(11) (2001) 837-850
Ishida, Effect of alloying elements on the shape memory properties of ductile Cu-Al-Mn alloys, Materials Science and Engineering: A 273 (1999) 375-379
Kim, Effects of aging treatments on transformation temperatures and precipitation kinetics in a Cu-Zn-Al shape-memory alloy, Journal of materials science 21(8) (1986) 2711-2715
Cui, Effect of precipitation during parent phase aging on the microstructure and properties of a refined Cu-Al-Mn shape memory alloy, Materials Science and Engineering: A 737 (2018) 124-131
Van Humbeeck, Shape memory alloys: a material and a technology, Advanced engineering materials 3(11) (2001) 837-850
Ishida, Effect of alloying elements on the shape memory properties of ductile Cu-Al-Mn alloys, Materials Science and Engineering: A 273 (1999) 375-379
Kim, Effects of aging treatments on transformation temperatures and precipitation kinetics in a Cu-Zn-Al shape-memory alloy, Journal of materials science 21(8) (1986) 2711-2715
Cui, Effect of precipitation during parent phase aging on the microstructure and properties of a refined Cu-Al-Mn shape memory alloy, Materials Science and Engineering: A 737 (2018) 124-131