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Online since: October 2010
Authors: Shu Bo Li, Zhi Qiang Lan, Zhao Lu, Jin Guo
Ti-based alloys are also considered to be one of the most promising materials for electrode materials, because of their high hydrogen capacity and relatively good kinetics.
The Materials Data Inc. software Jade 5.0 and a Powder Diffraction File (PDF release 2002) were used to determine the phase relationships [6].
Acknowledgments This work was supported by the Foundation of Key Laboratory of National Education Ministry for Nonferrous Metals and Materials Processing Technology (GXKFJ-09), the National Natural Science Foundation of China (Grant 50861003) and the Natural Science Foundation of Guangxi (Grant No. 2010GXNSFD013004) References [1] Y.
Vol. 32(2007),P.2412 [6] Materials Data JADE Release 5, XRD Pattern Processing, Materials Data Inc., 1999
Materials Science and Engineering .
The Materials Data Inc. software Jade 5.0 and a Powder Diffraction File (PDF release 2002) were used to determine the phase relationships [6].
Acknowledgments This work was supported by the Foundation of Key Laboratory of National Education Ministry for Nonferrous Metals and Materials Processing Technology (GXKFJ-09), the National Natural Science Foundation of China (Grant 50861003) and the Natural Science Foundation of Guangxi (Grant No. 2010GXNSFD013004) References [1] Y.
Vol. 32(2007),P.2412 [6] Materials Data JADE Release 5, XRD Pattern Processing, Materials Data Inc., 1999
Materials Science and Engineering .
Online since: May 2024
Authors: El Moustapha Elhaj-Maham, Moise Manga, Babacar Diouf, El Hadji Babacar Ly
Materials Today: Proceedings. 2020; 27: 1218–23
Afrique science. 2016;12:119–29
Construction and Building Materials. 2005;19:313–8
Construction and Building Materials. 2008;22:222–7
Construction and Building Materials. 2018;159:9–17
Afrique science. 2016;12:119–29
Construction and Building Materials. 2005;19:313–8
Construction and Building Materials. 2008;22:222–7
Construction and Building Materials. 2018;159:9–17
Online since: July 2015
Authors: Nur Izzati Ismail, Nadya Hussin Al Sbani, Omar Hamed Jehawi, Siti Rozaimah Sheikh Abdullah, Mushrifah Idris, Hassimi Abu Hasan
Materials and Methods
Propagation of S. grossus and preparation of synthetic mining wastewater.
Oh, Enhancement of heavy metal phytoremediation by Alnus firma with endophytic Bacillus thuringiensis GDB-1, Journal of Hazardous Materials. 250– 251 (2013) 477– 483
Poonia, Role of hyperaccumulators in phytoextraction of metals from contaminated mining sites: A review, Environmental Science and Technology. 41 (2011) 168-214
Fizri, Hyperaccumulation of copper by two species of aquatic plants, 2011 International Conference on Environmental Science and Engineering.
Hedbavny, Effect of aluminium uptake on physiology, phenols and amino acids in Matricaria chamomilla plants, Journal of Hazardous Materials. 178 (2010) 949–955
Oh, Enhancement of heavy metal phytoremediation by Alnus firma with endophytic Bacillus thuringiensis GDB-1, Journal of Hazardous Materials. 250– 251 (2013) 477– 483
Poonia, Role of hyperaccumulators in phytoextraction of metals from contaminated mining sites: A review, Environmental Science and Technology. 41 (2011) 168-214
Fizri, Hyperaccumulation of copper by two species of aquatic plants, 2011 International Conference on Environmental Science and Engineering.
Hedbavny, Effect of aluminium uptake on physiology, phenols and amino acids in Matricaria chamomilla plants, Journal of Hazardous Materials. 178 (2010) 949–955
Online since: December 2012
Authors: Hong Tao Hu
All of them were analytical reagent (AR).
2 Experimental scheme
In the experiment, pulverized coal ash, zeolite, fine sand, granular activated carbon, Fe and etc. were used as the activated materials of PRBs.
The activated materials were mixed and filled into special mesh bag and then fixed in porous plastic rectangle box as a modular unit to facilitate the replacement and addition of reactive material in PRB when it was saturated and invalidated.
[2] Zheng Shenshen:Journal of Agro-Environment Science,vol.26(2007), p.443-448, (in Chinese)
[7] Long Xingxian: Chinese Journal of Applied Ecology, vol.13(2002), p.757-762 (in Chinese)
[18] Ding Sa, Luo Yatian:Wuyi Science Journal,vol.23(2007), p.53-57 (in Chinese)
The activated materials were mixed and filled into special mesh bag and then fixed in porous plastic rectangle box as a modular unit to facilitate the replacement and addition of reactive material in PRB when it was saturated and invalidated.
[2] Zheng Shenshen:Journal of Agro-Environment Science,vol.26(2007), p.443-448, (in Chinese)
[7] Long Xingxian: Chinese Journal of Applied Ecology, vol.13(2002), p.757-762 (in Chinese)
[18] Ding Sa, Luo Yatian:Wuyi Science Journal,vol.23(2007), p.53-57 (in Chinese)
Online since: May 2018
Authors: Peng Cao, Hui Ping Tang, Muhammad Dilawer Hayat, Gang Chen, Shifaz Khan, Nan Liu
Bhaduri, Manufacturing and processing of NiTi implants: A review, Progress in Materials Science, 57 (2012) 911-946
Mertmann, M. de Wild, Tailoring Selective Laser Melting Process Parameters for NiTi Implants, Journal of Materials Engineering and Performance, 21 (2012) 2519-2524
Petzoldt, Machining of NiTi based shape memory alloys, Materials Science and Engineering: A, 378 (2004) 180-184
Ren, Physical metallurgy of Ti–Ni-based shape memory alloys, Progress in Materials Science, 50 (2005) 511-678
Pollock, Processing of TiNi from elemental powders by hot isostatic pressing, Materials Science and Engineering: A, 280 (2000) 334-348.
Mertmann, M. de Wild, Tailoring Selective Laser Melting Process Parameters for NiTi Implants, Journal of Materials Engineering and Performance, 21 (2012) 2519-2524
Petzoldt, Machining of NiTi based shape memory alloys, Materials Science and Engineering: A, 378 (2004) 180-184
Ren, Physical metallurgy of Ti–Ni-based shape memory alloys, Progress in Materials Science, 50 (2005) 511-678
Pollock, Processing of TiNi from elemental powders by hot isostatic pressing, Materials Science and Engineering: A, 280 (2000) 334-348.
Online since: March 2015
Authors: Sheng Qiang, Er Zhao Lou, Lian Jian Liu, Yan Bo Ni, Jian Bo Jiang, Guang Pu Hou
Since there are many well-known comprehensive heat and mass transfer models of porous media both at home and abroad, for different materials and environment, it is necessary to choose a appropriate model.
[3] Kham AA, Cook W D: ACI Materi-al Journal,1998,95:293-302 [4] Mingrong Mei, Qingwen Ren: Advances in Science and Technology of Water Resources, 2002, 22(3): 59-62, in Chinese
[6] Guangting Liu, Dahai Huang: Journal of Building Materials, 2003, 6(2): 173-181, in Chinese
Weng: International Journal Of Heat and Mass Transfer, 2000, 43(19): 3621-3632
[11] Saetta A V, in: Journal of Materials in Civil Engineering, 2005, 17(3):313-319.
[3] Kham AA, Cook W D: ACI Materi-al Journal,1998,95:293-302 [4] Mingrong Mei, Qingwen Ren: Advances in Science and Technology of Water Resources, 2002, 22(3): 59-62, in Chinese
[6] Guangting Liu, Dahai Huang: Journal of Building Materials, 2003, 6(2): 173-181, in Chinese
Weng: International Journal Of Heat and Mass Transfer, 2000, 43(19): 3621-3632
[11] Saetta A V, in: Journal of Materials in Civil Engineering, 2005, 17(3):313-319.
Online since: September 2018
Authors: Yu.V. Pukharenko, Alexander V. Klyuev, Tolya Khezhev, Sergei V. Klyuev
Lemm, Fiber-Reinforced Concrete: Principles, Properties, Developments and Applications (Building Materials Science), William Andrew; The illustrated edition Feb, 1990
Durachenko, High-Strength Fiber-Reinforced Concrete Containing Technogenic Raw Materials and Composite Binders with Use of Nano-dispersed Powder, Research Journal of Applied Sciences. 9 (2014) 1153 – 1157
Durachenko, Fine-Grain concrete reinforced by polypropylene fiber, Research Journal of Applied Sciences. 10 (10) (2015) 624 – 628
Durachenko, The Development of textile fine-grained fiber concrete using technogenic raw materials, Research Journal of Applied Sciences. 10 (10) (2015) 701 – 706
Klyuev Fiber Gypsum Concrete Composites with Using Volcanic Tuff Sawing Waste, ARPN Journal of Engineering and Applied Sciences. 13 (8) 2018 2935 – 2946.
Durachenko, High-Strength Fiber-Reinforced Concrete Containing Technogenic Raw Materials and Composite Binders with Use of Nano-dispersed Powder, Research Journal of Applied Sciences. 9 (2014) 1153 – 1157
Durachenko, Fine-Grain concrete reinforced by polypropylene fiber, Research Journal of Applied Sciences. 10 (10) (2015) 624 – 628
Durachenko, The Development of textile fine-grained fiber concrete using technogenic raw materials, Research Journal of Applied Sciences. 10 (10) (2015) 701 – 706
Klyuev Fiber Gypsum Concrete Composites with Using Volcanic Tuff Sawing Waste, ARPN Journal of Engineering and Applied Sciences. 13 (8) 2018 2935 – 2946.
Online since: June 2013
Authors: Richard Landfried, Frank Kern, Rainer Gadow
Besides the wear resistance, high strength and toughness are necessary for mold materials to withstand the loads during application.
This layer additionally to the higher vaporization point of zirconia hinders the machining process of zirconia based materials and therefore lowers the removal rate.
-C., Microstructure and Tool Electrode Erosion in EDMed of TiN/Si3N4 Composites, Materials Science and Engineering, 363, 21–227, 2003 [4] B.
Van der Biest, Toughness tailoring of yttria-doped zirconia ceramics, Materials Science and Engineering, A380, 215-221, (2004) [5] P.
Marshall, A Critical Evaluation of Indentation Techniques for Measuring Fracture Toughness: II - Strength Method, Journal of American Ceramic Society, Vol. 64, No. 9, (1981) [6] Ran, S. and Gao, L., Electrical properties and microstructural evolution of ZrO2-Al2O3-TiN nanocomposites prepared by spark plasma sintering, Ceramics International, 38, pp. 4923-4928, 2012 [7] Lux, F., Review - Models proposed to explain the electrical conductivity of mixtures made of conductive and insulating materials, Journal of Materials Science, 28, pp. 285-301, 1993 [8] Malliaris, A. and Turner, D.T., Influence of Particle Size on the Electrical Resistivity of Compacted Mixtures of Polymeric and Metallic Powders, Journal of Applied Physics, Volume 42, Number 2, pp.614-618, 1971 [9] Chase, M.W; Davies, C.A.; Downey, J.R.; Frurip, D.J.; McDonald, R.A. and Syverud, A.N.:, JANAF Thermochemical Tables, 3rd edition, J.Phys.
This layer additionally to the higher vaporization point of zirconia hinders the machining process of zirconia based materials and therefore lowers the removal rate.
-C., Microstructure and Tool Electrode Erosion in EDMed of TiN/Si3N4 Composites, Materials Science and Engineering, 363, 21–227, 2003 [4] B.
Van der Biest, Toughness tailoring of yttria-doped zirconia ceramics, Materials Science and Engineering, A380, 215-221, (2004) [5] P.
Marshall, A Critical Evaluation of Indentation Techniques for Measuring Fracture Toughness: II - Strength Method, Journal of American Ceramic Society, Vol. 64, No. 9, (1981) [6] Ran, S. and Gao, L., Electrical properties and microstructural evolution of ZrO2-Al2O3-TiN nanocomposites prepared by spark plasma sintering, Ceramics International, 38, pp. 4923-4928, 2012 [7] Lux, F., Review - Models proposed to explain the electrical conductivity of mixtures made of conductive and insulating materials, Journal of Materials Science, 28, pp. 285-301, 1993 [8] Malliaris, A. and Turner, D.T., Influence of Particle Size on the Electrical Resistivity of Compacted Mixtures of Polymeric and Metallic Powders, Journal of Applied Physics, Volume 42, Number 2, pp.614-618, 1971 [9] Chase, M.W; Davies, C.A.; Downey, J.R.; Frurip, D.J.; McDonald, R.A. and Syverud, A.N.:, JANAF Thermochemical Tables, 3rd edition, J.Phys.
Online since: August 2013
Authors: Jun Wei Shi
Chinese scholars included LIU Zhi-xiang (LIU et al.,2004),using cemented tailings for filling materials [1]; YAO Jian (YAO et al.,2006) ,using phos-phogypsum and fly ash cemented as filling materials[2]; ZHAO Cai-zhi (ZHAO et al.,2008) ,using PL paste cementing material (ordinary Portland cement, gyp-sum, lime and many kinds of admixture composed), fly ash, SiHe’s sand for filling materials[3]; WEI Xiu-quan (WEI et al.,2009), CUI Zeng-di (CUI et al.,2010), HE Li-hui (HE et al.,2011) and LI Meng (LI et al.,2012),using coal gangue, fly ash as the main aggregate of coal gangue setting fill materials, experimentizing the paste filling material on the mechanical properties respectively, and elastic modulus, strength and deformation performance of filling material was studied[4-7].
Filling body can reach engineering strength requirements af-ter plastic strengthen and then users can reduce the cost of filling materials to achieve better economic benefits.
Experimental research on phosphogypsum and fly ash cementation filling materials.
CUMT Journal, 33(2):159-161 [4] X Q Wei, H H Sun, Y Y Wang, 2009.
Journal of china coal society, 35(6):896-899 [6] M Li , J F X, G Y Song, 2012.
Filling body can reach engineering strength requirements af-ter plastic strengthen and then users can reduce the cost of filling materials to achieve better economic benefits.
Experimental research on phosphogypsum and fly ash cementation filling materials.
CUMT Journal, 33(2):159-161 [4] X Q Wei, H H Sun, Y Y Wang, 2009.
Journal of china coal society, 35(6):896-899 [6] M Li , J F X, G Y Song, 2012.
Online since: October 2014
Authors: Xiang Jie Yang, Yong Xu, Xiong Xin Jiang, Yi He, Dan Ni Du
Materials Science and Engineering A. 549(2012)163-167
Materials Science and Engineering A. 279(2000)289–299
Materials Science & Engineering A. 593 (2014)16–23
Materials Science and Engineering A. 243(1998)82-88
Journal of Materials Processing Technology. 71(1997)377-383
Materials Science and Engineering A. 279(2000)289–299
Materials Science & Engineering A. 593 (2014)16–23
Materials Science and Engineering A. 243(1998)82-88
Journal of Materials Processing Technology. 71(1997)377-383