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Online since: April 2014
Authors: Ren Bo Song, San Chuan Yu, Qi Feng Dai, Zhe Gao
Materials Science and Engineering A. 391 (2005) 296–304
Materials Science and Engineering A. 480 (2008) 540–548
Material Science and Technology. 21 (2013) 6-13
Materials Letters. 62 (2008) 327 – 329
Materials Science and Engineering A. 527 (2010) 5410–5414
Materials Science and Engineering A. 480 (2008) 540–548
Material Science and Technology. 21 (2013) 6-13
Materials Letters. 62 (2008) 327 – 329
Materials Science and Engineering A. 527 (2010) 5410–5414
Online since: November 2013
Authors: Zhe Wang, Ning Zhang, Si Yao Sui, Zhong Su Ma
Edible films based on agricultural materials have received much attention as potential packaging materials, principally because such biodegradable films are considered to be a promising solution to environmental impacts of synthetic polymer packaging (Rhim & Lee, 2004; Su, Huang, Yuan, Wang & Li, 2010; Yin, Tang, Wen & Yang, 2007).
Of the naturally occurring edible materials, soy protein has been widely studied due to its low cost, availability, and complete biodegradability (Mauri & Anon, 2008).
Materials and Methods Soy protein isolate was obtained from Gushen Biotechnology Group Ltd.
Alvarez Igarzabal, 2011 "Cross-linked soy protein as material for biodegradable films: Synthesis, characterization and biodegradation", "Journal of Food Engineering", Vol.106, No.4, pp. 331-338
Wang, 2011 "Biodegradable Soy Protein Isolate-Based Materials: A Review", "Biomacromolecules", Vol.12, No.10, pp3369-3380
Of the naturally occurring edible materials, soy protein has been widely studied due to its low cost, availability, and complete biodegradability (Mauri & Anon, 2008).
Materials and Methods Soy protein isolate was obtained from Gushen Biotechnology Group Ltd.
Alvarez Igarzabal, 2011 "Cross-linked soy protein as material for biodegradable films: Synthesis, characterization and biodegradation", "Journal of Food Engineering", Vol.106, No.4, pp. 331-338
Wang, 2011 "Biodegradable Soy Protein Isolate-Based Materials: A Review", "Biomacromolecules", Vol.12, No.10, pp3369-3380
Online since: September 2011
Authors: Yu Xiang Lu, Guo Liang Qi, Liang Cheng
First-Principles Calculation for Improving Room Temperature
Ductility of B2-NiAl by Fe
LU Yu-xiang1,a, QI Guo-liang, CHENG Liang
1Department of Materials Engineering, China University of Petroleum(East China), Dongying, Shan Dong Province, P R China 257061
acl12aa@163.com
Key words: DFT; NiAl; room temperature ductility; intermetallic compound
Abstract.
It is a class of promising high temperature structural materials [1,2].
By analysing bonding characteristics of the B2-NiAl, we know that material’s ductility is closely related to the bonding directionality between atoms [17].
Fleischer:Journal of Materials Science.
Vol.22 (1987),p. 2281 [2] Z.Y.Gu:Materials Science Progress.Vol.4 (1990),p. 132 [3] H.J.Grabke:Intermetallics.Vol.7(1999),p. 1153 [4] R.D.Noeboe: International materials reviews.Vol.38 (1993),p.193 [5] D.B.Miracle: Acta Metallurgica et Materialia.Vol.41 (1993),p.649 [6] K.H.Hahn:Scripta Metallurgica.Vol.23(1989),p.7 [7] K.Ishida:Metallurgical Transactions A.Vol.22 (1991),p.441 [8] E.P.George: Journal of Materials Research.Vol.5 (1990),p.754 [9] R.Darolia:Scripta Metallurgica et Materialia.Vol.26(1992),p.1007 [10] J.H.Yang:Materials Science & Engineering.Vol.160(1993),p.241 [11] R.Kainuma:Metallurgical and Materials Transactions A.Vol.23(1992),p.1147 [12] P.R.Munroe:Materials Science & Engineering A.Vol.325 (2002),p.1 [13] Y.X.Lu:Harbin institute of technology. 1997 [14] Y.J.Hu:The Chinese Journal of Non-ferrous Metals.Vol.14 (2004),p.2102 [15] J.T.Guo: Beijing: Science Press.2003,p.3 [16] D.A.Muller: Physical Review B.
It is a class of promising high temperature structural materials [1,2].
By analysing bonding characteristics of the B2-NiAl, we know that material’s ductility is closely related to the bonding directionality between atoms [17].
Fleischer:Journal of Materials Science.
Vol.22 (1987),p. 2281 [2] Z.Y.Gu:Materials Science Progress.Vol.4 (1990),p. 132 [3] H.J.Grabke:Intermetallics.Vol.7(1999),p. 1153 [4] R.D.Noeboe: International materials reviews.Vol.38 (1993),p.193 [5] D.B.Miracle: Acta Metallurgica et Materialia.Vol.41 (1993),p.649 [6] K.H.Hahn:Scripta Metallurgica.Vol.23(1989),p.7 [7] K.Ishida:Metallurgical Transactions A.Vol.22 (1991),p.441 [8] E.P.George: Journal of Materials Research.Vol.5 (1990),p.754 [9] R.Darolia:Scripta Metallurgica et Materialia.Vol.26(1992),p.1007 [10] J.H.Yang:Materials Science & Engineering.Vol.160(1993),p.241 [11] R.Kainuma:Metallurgical and Materials Transactions A.Vol.23(1992),p.1147 [12] P.R.Munroe:Materials Science & Engineering A.Vol.325 (2002),p.1 [13] Y.X.Lu:Harbin institute of technology. 1997 [14] Y.J.Hu:The Chinese Journal of Non-ferrous Metals.Vol.14 (2004),p.2102 [15] J.T.Guo: Beijing: Science Press.2003,p.3 [16] D.A.Muller: Physical Review B.
Online since: February 2011
Authors: Jian Zhong Cui, Jin Tao Li, Guang Ming Xu
It has been determined that the application of a magnetic field during the directional solidification of materials can significantly reduce convective flow in the melt [6, 7].
Hunt: Journal of Materials Processing Technology Vol. 55(1995), p.76–84
Edmonds: Journal of Materials Processing Technology Vol. 83(1998), p.1-13
Hunt: Materials Science and Engineering A Vol. 280(2000), p.116-123
Gu: Journal of Northeastern University (Natural Science) Vol. 25(2004), p.48-50, In Chinese.
Hunt: Journal of Materials Processing Technology Vol. 55(1995), p.76–84
Edmonds: Journal of Materials Processing Technology Vol. 83(1998), p.1-13
Hunt: Materials Science and Engineering A Vol. 280(2000), p.116-123
Gu: Journal of Northeastern University (Natural Science) Vol. 25(2004), p.48-50, In Chinese.
Online since: February 2016
Authors: Ksenia Machekhina, Vladimir An, Yuriy Irtegov, Nikolay Lemachko
Application of nanoscale and nanostructured WS2 and MoS2 particles is not limited to tribotechnical compositions [1, 2] and polymer additives [3], these materials are used as high-energy density lithium-ion battery elements [4], effective desulfurization catalysts [5].
Zakharov, Properties of WS2 films prepared by magnetron sputtering from a nanostructured target, Advanced Materials Research 872 (2014) 197-200
Journal of Refractory Metals & Hard Materials 27 (2009) 149-154
Ishigaki, The preparation and characterization of ultrafine tungsten powder, Journal of Materials Science Letters 16 (1997) 347-349
An, Study of tungsten and molybdenum nanopowders interaction with sulphur in SHS conditions and synthesized product properties, Advanced Materials Research 1040 (2014) 171-175.
Zakharov, Properties of WS2 films prepared by magnetron sputtering from a nanostructured target, Advanced Materials Research 872 (2014) 197-200
Journal of Refractory Metals & Hard Materials 27 (2009) 149-154
Ishigaki, The preparation and characterization of ultrafine tungsten powder, Journal of Materials Science Letters 16 (1997) 347-349
An, Study of tungsten and molybdenum nanopowders interaction with sulphur in SHS conditions and synthesized product properties, Advanced Materials Research 1040 (2014) 171-175.
Online since: September 2013
Authors: Ping Zou, Wen Bo Zhou, Pei Shi Sun, Xiao Yi Bi, Yong Yang Mao, Xiao Yun Zheng
Fig. 1 Diagram of experimental setup Fig. 2 Color comparison diagram
Materials and Methods
Leach ore experiment
Copper ore and the leach agent.
Preparation of fertilizers experiment Raw materials.
The raw materials were the two liquids (Liquid S and Liquid N) and the main components were individually listed in Table 2.
Journal of Environmental Sciences, 21.3 (2009): 328-332
Journal of Energetic Materials, 31.1 (2013): 1-26
Preparation of fertilizers experiment Raw materials.
The raw materials were the two liquids (Liquid S and Liquid N) and the main components were individually listed in Table 2.
Journal of Environmental Sciences, 21.3 (2009): 328-332
Journal of Energetic Materials, 31.1 (2013): 1-26
Online since: August 2014
Authors: Hua Lin, You Xi Lin, Zhen Wei Han
Experimental
Workpiece material.
Adhesion of the workpiece materials onto the flank face of the tool is also observed in Fig.4(d).
Acknowledgment The authors would like to acknowledge the support of the National Natural Science Foundation of China (Grant No. 51375094) and the Natural Science Foundation of Fujian Province, China(Grant No. 2013J0101 ).
Journal of Materials Processing Technology.
Journal of Materials Processing Technology.
Adhesion of the workpiece materials onto the flank face of the tool is also observed in Fig.4(d).
Acknowledgment The authors would like to acknowledge the support of the National Natural Science Foundation of China (Grant No. 51375094) and the Natural Science Foundation of Fujian Province, China(Grant No. 2013J0101 ).
Journal of Materials Processing Technology.
Journal of Materials Processing Technology.
Online since: October 2007
Authors: G.P. Martins, Tawiwan Kangsadan, Grant Scott, Jeff Van Hoose, Christopher Wagner
Martins 1,a
, Tawiwan Kangsadan 2,b
, Grant Scott 3,c
Christopher Wagner 4,d
and Jeff Van Hoose 5,e
1
Dept. of Metallurgical and Materials Engineering
Colorado School of Mines, Golden, CO 80401, USA
2
King Mongkut's Institute of Technology North Bangkok
1518 Pibulsongkram Road, Bangsue, Bangkok 10800 Thailand
3
Hazen Research, Inc
4601 Indiana Street, Golden, CO 80403, U.S.A.
4
First Solar Inc.
28101 Cedar Park Drive, Perrysburg , OH 43551, USA
5
Coors Tech
600 9th.
During the last decade, a comprehensive research program on the production of molybdenum powder by reduction of hexavalent compounds with hydrogen has been conducted in the Metallurgical and Materials Engineering Department at the Colorado School of Mines (CSM) [8,9,10,11,12].
Langston: Hydrogen Reduction of Molybdic Oxide, Journal of Metals, Vol.16, (1964), pp. 877-884
Ortner: Mechanisms of the Hydrogen Reduction of Molybdenum Oxides, International Journal of Refractory Metals & Hard Materials, Vol. 20, (2002), pp. 261-269
Advances in Powder Metallurgy & Particulate Materials, (2003), pp.198-209
During the last decade, a comprehensive research program on the production of molybdenum powder by reduction of hexavalent compounds with hydrogen has been conducted in the Metallurgical and Materials Engineering Department at the Colorado School of Mines (CSM) [8,9,10,11,12].
Langston: Hydrogen Reduction of Molybdic Oxide, Journal of Metals, Vol.16, (1964), pp. 877-884
Ortner: Mechanisms of the Hydrogen Reduction of Molybdenum Oxides, International Journal of Refractory Metals & Hard Materials, Vol. 20, (2002), pp. 261-269
Advances in Powder Metallurgy & Particulate Materials, (2003), pp.198-209
Online since: February 2012
Authors: Asaad A. Abdullah, Usama J. Naeem, Cai Hua Xiong
The authors thank HUST (Huazhong University of Science and Technology), School of Mechanical Science and Engineering.
Materials and Design 2007; 28:1618–1622
International Journal of Machine Tools & Manufacture 2005; 45: 467–479
Journal of Materials Processing Technology 2007;189:192–198
Materiali in tehnologije / Materials and technology 2009; 43(5): 267–270
Materials and Design 2007; 28:1618–1622
International Journal of Machine Tools & Manufacture 2005; 45: 467–479
Journal of Materials Processing Technology 2007;189:192–198
Materiali in tehnologije / Materials and technology 2009; 43(5): 267–270
Online since: January 2015
Authors: Kai Xu, Hui Qing Peng, De Ge Ji Rifu, Rui Xin Zhang, Hao Xiao, Qian Shi
Jiangxi University of Science and Technology, Ganzhou 341000, China
2.
Materials and Methods 2.1.
Hydrological Sciences Journal-Journal Des Sciences Hydrologiques, 2008, 53(5): 977-988
Journal of Hydrology, 2005, 312(1-4): 207-222
Journal of Hydrology, 1970, 10(3): 282-290
Materials and Methods 2.1.
Hydrological Sciences Journal-Journal Des Sciences Hydrologiques, 2008, 53(5): 977-988
Journal of Hydrology, 2005, 312(1-4): 207-222
Journal of Hydrology, 1970, 10(3): 282-290