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Online since: April 2015
Authors: Dong Hui Yang, Hui Wang, Zhong Yun Hu, Wei Ping Chen, Jian Qing Chen, Jing Hua Jiang, Aibin Ma
Experiments
Materials and Foamable Precursor Preparation.
Wang, et al., Compressive properties of cellular Mg foams fabricated by melt-foaming method, Materials Science and Engineering: A. 527(21) (2010) 5405-5409
Sakaguchi, et al., Processing of an open-cellular AZ91 magnesium alloy with a low density of 0.05 g/cm3, Journal of Materials Science Letters. 18(18) (1999) 1477-1480
Zhang, et al., Evolution of pore size distribution and mean pore size in lotus-type porous magnesium fabricated with gasar process, Journal of Materials Science & Technology. 22(3) (2006) 306-310
Banhart, A study of Mg and Cu additions on the foaming behaviour of Al–Si alloys, Journal of Materials Science. 46(15) (2011) 5227-5236
Wang, et al., Compressive properties of cellular Mg foams fabricated by melt-foaming method, Materials Science and Engineering: A. 527(21) (2010) 5405-5409
Sakaguchi, et al., Processing of an open-cellular AZ91 magnesium alloy with a low density of 0.05 g/cm3, Journal of Materials Science Letters. 18(18) (1999) 1477-1480
Zhang, et al., Evolution of pore size distribution and mean pore size in lotus-type porous magnesium fabricated with gasar process, Journal of Materials Science & Technology. 22(3) (2006) 306-310
Banhart, A study of Mg and Cu additions on the foaming behaviour of Al–Si alloys, Journal of Materials Science. 46(15) (2011) 5227-5236
Online since: June 2014
Authors: Bin Hu, Xiao Ning Zhang
Journal of Materials in Civil Engineering, Vol. 16 (2004) No.2, p.167-174
Journal of Transport Science and Engineering, Vol. 26 (2010) No.2, p.1-8
Journal of Shenzhen University Science and Engineering, Vol. 23 (2006) No.4, p.296-302
Journal of Tongji University (Natural Science), Vol. 38 (2010) No.12, p.1792-1795
Journal of Central South University (Science and Technology), Vol. 43 (2012) No.7, p.1-8
Journal of Transport Science and Engineering, Vol. 26 (2010) No.2, p.1-8
Journal of Shenzhen University Science and Engineering, Vol. 23 (2006) No.4, p.296-302
Journal of Tongji University (Natural Science), Vol. 38 (2010) No.12, p.1792-1795
Journal of Central South University (Science and Technology), Vol. 43 (2012) No.7, p.1-8
Online since: August 2015
Authors: Tadeusz A. Przylibski
Chalupnik, Correlation of radon concentration level with mining and geological conditions in Upper Silesia region, Journal of Mining Science 39 (2) (2003) 199-206
Kotyrba, Radon mapping with the support of geophysical methods, Journal of Mining Science 47 (3) (2011) 330-337
Michalik, System of radiation hazard monitoring and control in the coal mines of Poland, Journal of Mining Science 38 (6) (2002) 587-595
Wysocka, Measurement of radon exhalation from soil – development of the method and preliminary results, Journal of Mining Science 39 (2) (2003) 191-198
Rubin, Radon exhalation from cement-matrix composites in the function of technological parameters, Ceramic Materials 62 (4) (2010) 591-595.
Kotyrba, Radon mapping with the support of geophysical methods, Journal of Mining Science 47 (3) (2011) 330-337
Michalik, System of radiation hazard monitoring and control in the coal mines of Poland, Journal of Mining Science 38 (6) (2002) 587-595
Wysocka, Measurement of radon exhalation from soil – development of the method and preliminary results, Journal of Mining Science 39 (2) (2003) 191-198
Rubin, Radon exhalation from cement-matrix composites in the function of technological parameters, Ceramic Materials 62 (4) (2010) 591-595.
Online since: April 2013
Authors: Maisarah Mohamed Bazin, Norhayati Ahmad, Yuzo Nakamura, Hiroki Kamibayasi
bDepartment of Nanostructured and Advanced Materials, Kagoshima University, 1-21-40 Korimoto, Kagoshima, 890-0065 JAPAN.
Abstract: The fabrication of low cost ceramic membranes for microfiltration were studied by using a natural materials (shirasu balloon) which are produced from glassy volcanic materials.
Fine shirasu balloons are produce from glassy volcanic materials called shirasu.
Larbot and S.Cerneaux, New Clay-Alumina Porous Capillary Supports for Filtration Appication, Journal of Membrane Science, 2010
Matsuura, Mechanical and Pore Characteristic of Zeolite Composite Membranes, Journal of Materials Chemistry, 1999, 9, 783-788.
Abstract: The fabrication of low cost ceramic membranes for microfiltration were studied by using a natural materials (shirasu balloon) which are produced from glassy volcanic materials.
Fine shirasu balloons are produce from glassy volcanic materials called shirasu.
Larbot and S.Cerneaux, New Clay-Alumina Porous Capillary Supports for Filtration Appication, Journal of Membrane Science, 2010
Matsuura, Mechanical and Pore Characteristic of Zeolite Composite Membranes, Journal of Materials Chemistry, 1999, 9, 783-788.
Online since: June 2021
Authors: Libasse Sow, Siham Kamali-Bernard, Fabrice Bernard
Computational Materials Science, 50(1) (2010) 218-226
Computational Materials Science, 61 (2012) 106-115
Computational Materials Science, 102 (2015) 250-257
Computational Materials Science, 45(2) (2009) 528-535
Computational Materials Science, 47 (2009b) 178-185
Computational Materials Science, 61 (2012) 106-115
Computational Materials Science, 102 (2015) 250-257
Computational Materials Science, 45(2) (2009) 528-535
Computational Materials Science, 47 (2009b) 178-185
Online since: March 2012
Authors: Yuan Rui Wang, Guo Jun Qiang, Feng Juan Liu
Liu, J.E.Zhou and A.Larbot:Journal of Materials Processing Technology Vol.189(2007), p. 379-383
[3] W.W.Wu , Q.Y.Jiang: Materials Letters Vol.60(2006),p.2791-2794
[4] M.
Sato, H.Harada, and S.Morito: Applied Surface Science Vol.256 (2010),p.4497-4501 [5] M.
Crnjak Orel: Journal of the European Ceramic Society Vol.28 (2008),p.2915-2921 [6] S.J.Chena, L.H.
Lia and X.T.Chen: Journal of Crystal Growth Vol.252(2003), p.184-189 [7] C.S.Lin, C.C.Hwang and W.H.Lee: Materials Science and Engineering B Vol.140(2007),p. 31- 37
[8] C.L.Kuo, C.L.Wang and H.H.Ko: Ceramics International Vol.36(2010),p.693- 698 [9] O.Acarbas, E.Suvacı and A.Dogan: Ceramics International Vol.33( 2007), p.537-542 [10] K.C.Song , Y.Kang: Materials Letters Vol.42(2000), p.283-289 [11] T.Wang, Z.N.Ma and F.Xu: Electrochemistry Communications Vol.5.(2003),p.599-602 [12] S.Li, X.L.Qiao and J.G.Chen:Journal of Crystal Growth Vol.289(2006),p.151-156 [13] H.Yang , S.D.Han and L.Wang: Materials Chemistry and Physics Vol.56(1998),p.153-156 [14] F.Davar , F.Mohandes and M.S.Niasari.: Polyhedron Vol.29(2010) , p.3132-3136 [15] C.Cobianu, C.Savaniu and O.Buiu: Sensors and Actuators B Vol.43(1997),p.114-120.
Sato, H.Harada, and S.Morito: Applied Surface Science Vol.256 (2010),p.4497-4501 [5] M.
Crnjak Orel: Journal of the European Ceramic Society Vol.28 (2008),p.2915-2921 [6] S.J.Chena, L.H.
Lia and X.T.Chen: Journal of Crystal Growth Vol.252(2003), p.184-189 [7] C.S.Lin, C.C.Hwang and W.H.Lee: Materials Science and Engineering B Vol.140(2007),p. 31- 37
[8] C.L.Kuo, C.L.Wang and H.H.Ko: Ceramics International Vol.36(2010),p.693- 698 [9] O.Acarbas, E.Suvacı and A.Dogan: Ceramics International Vol.33( 2007), p.537-542 [10] K.C.Song , Y.Kang: Materials Letters Vol.42(2000), p.283-289 [11] T.Wang, Z.N.Ma and F.Xu: Electrochemistry Communications Vol.5.(2003),p.599-602 [12] S.Li, X.L.Qiao and J.G.Chen:Journal of Crystal Growth Vol.289(2006),p.151-156 [13] H.Yang , S.D.Han and L.Wang: Materials Chemistry and Physics Vol.56(1998),p.153-156 [14] F.Davar , F.Mohandes and M.S.Niasari.: Polyhedron Vol.29(2010) , p.3132-3136 [15] C.Cobianu, C.Savaniu and O.Buiu: Sensors and Actuators B Vol.43(1997),p.114-120.
Online since: July 2015
Authors: Reyhan Keskin, Guralp Ozkoc, Ikilem Göcek
Experimental
Materials and Method.
Pan: Journal of COMPOSITE MATERIALS Vol. 37 (2003), p. 1951-1969
Mai: Journal of Materials Science Vol. 36 (2001), p. 1243-1251
Lenz: Materials Research Ibero American Journal of Materials Vol. 11 (2008), p. 447-451
Smith: Journal of Materials Science Vol. 33 (1998), p. 5415-5422.
Pan: Journal of COMPOSITE MATERIALS Vol. 37 (2003), p. 1951-1969
Mai: Journal of Materials Science Vol. 36 (2001), p. 1243-1251
Lenz: Materials Research Ibero American Journal of Materials Vol. 11 (2008), p. 447-451
Smith: Journal of Materials Science Vol. 33 (1998), p. 5415-5422.
Online since: February 2014
Authors: Jian Bing Chen
Experimental
Materials
The type of PEEK 012P, which number-average molecular weight (Mn) was 60000, and PES, Mn 65000, which powder of 250 µm in diameter, were supplied by Changchun Jida Engineering Plastics Research Co., Ltd., in which PEEK material had a Tg of 143.3°C and a Tm of 335°C, and PES had also a Tg of 230.2°C.
Journal of Polymer Science: Part B: Polymer Physics, 40(2002), p. 1407-1424
Journal of Applied Polymer Science, 127(2013), p. 2220–2226
Chemical Journal of Chinese Universites, Vol.16 (1995), p. 120
Polymer Materials Science and Engineering, Vol. 25(2009 ), p. 87.
Journal of Polymer Science: Part B: Polymer Physics, 40(2002), p. 1407-1424
Journal of Applied Polymer Science, 127(2013), p. 2220–2226
Chemical Journal of Chinese Universites, Vol.16 (1995), p. 120
Polymer Materials Science and Engineering, Vol. 25(2009 ), p. 87.
Online since: May 2011
Authors: Chen Liang Zhou, Shu Yun Xu, Ke Duan Zhi, Run Xia He, Quan Sheng Liu, Qian Zhang
Chemistry Materials, Vol. 14(2002), p. 697
Chemistry Materials, Vol. 14(2002), p. 3844
Journal of Porous Materials, Vol. 5(1998), p. 153
Materials, Vol. 16(2004), p. 4330
Microporous Materials, Vol. 11(1997), p. l
Chemistry Materials, Vol. 14(2002), p. 3844
Journal of Porous Materials, Vol. 5(1998), p. 153
Materials, Vol. 16(2004), p. 4330
Microporous Materials, Vol. 11(1997), p. l