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Recovery of Silicon and Silicon Carbide Powder from Waste Silicon Wafer Sludge Woo-Teck Kwon1,a, Soo-Ryong Kim1,b, Younghee Kim1,c, Jeeban Poudel2,d and Sea Cheon Oh2, e* 1Green Ceramic Division, Korea Institute of Ceramic Engineering and Technology, 103 Fashion Danji-gil, Guemcheon-gu, Seoul, 153-801, Korea 2Department of Environmental Engineering, Kongju National University, 275 Budae-dong, Cheonan, Chungnam, 330-717, Korea awtkwon@kicet.re.kr, bsrkim@kicet.re.kr, yhkokim@kicet.re,kr, djeeban1985@gmail.com, eohsec@kongju.ac.kr Keywords: silicon, silicon carbide, silicon wafer sludge, diethylene glycol Abstract.
Oh: Materials Science Forum Vol. 724 (2012), p. 49-52 [2] Y.H.
Kwon: Advanced Materials Research Vols. 26-28 (2007), p.271-274 [3] D.
Stolt: Handbook of Photovoltaic Science and Engineering, Wiley and Sons, UK (2003)

The difractometer employed was a Bruker D8 Advance, using CuKα radiation.
Forum 426-432 (2003) 4307-4312
Forum 426-432 (2003) 4313-4318
Schoenung, Materials Science and Engineering A 493 (2008) 207-214
Cuevas, J.M Gallardo, Materials Science Forum 514-516 (2006) 1279-1283 [21] J.

Saimoto Mechanical and Materials Engineering, Nicol Hall, Queen's University, 60 Union Street, Kingston, ON, K7L3N6, CANADA.
Results and Discussion The engineering stress-strain curves for nominally pure Al tested at 27 °C (300 K) are shown in Fig. 1.
Acknowledgements The author thanks the Natural Sciences and Engineering Research Council of Canada, Novelis Inc.
Forum Vol. 331-337 (2000) p. 745
Forum Vol. 475-479 (2005) p. 421

In the aspects of Systems Engineering, we should realize systems’ character first of all, when applying SD method to research.
In Fig.2, an advance in the government and policy support, market demand and market competition pressure→an advance in enterprises’ innovation consciousness→an advance in their desire for establishing knowledge alliance→increase the demand for knowledge resources→increase the capital supplied by enterprises→increase the knowledge resources acquired by enterprises→promote the transformation capability of scientific & technical achievements→improve commercialization & industrialization degree of knowledge products→increase the benefits gained by enterprises→increase the total benefits of alliance→enhance the government and policy support→improve enterprises’ innovation consciousness.
At the same time, an advance in government & policy support→increase the benefits acquired by enterprises, universities & research institute→improve the level of scientific research→advance the development of science & technology→enhance the government and policy support.
Journal of Jiangsu Commercial Forum, 2006(12):146-148 [4] Wang Huipo.
Dissertation of Harbin Engineering University, 2007:115-117 [5] Wei Fei.

A NEW TECHNIQUE FOR THE RAPID MANUFACTURING OF DIRECTOXIDATION ANODES FOR SOFC's Nir Ben-Oved1,2,a , Olivera Kesler 1,2,b 1 Department of Mechanical Engineering, University of British Columbia, 2054-6250 Applied Science Lane, Vancouver, BC V6T 1Z4, CANADA 2 NRC Institute for Fuel Cell Innovation, 3250 East Mall, Vancouver, BC V6T 1W5, CANADA a benoved@interchange.ubc.ca, bkesler@mech.ubc.ca Keywords: Plasma spray, Cu-based anode, SOFC, direct oxidation Abstract: A new rapid manufacturing technique for the production of SOFC anodes for direct oxidation of hydrocarbon fuels has been demonstrated.
SDC powder (Ce0.8Sm0.2O1.9, Inframat Advanced Materials, particle size 45 µm-75 µm), and CuO powder (Inframat Advanced Materials, particle size 45 µm-75 µm) with a weight ratio of 1.5 g SDC to 1g of CuO were dry ball milled for several hours to thoroughly mix the two powders.
Acknowledgements The authors gratefully acknowledge the generous financial support of the Advanced Systems Institute of BC for the preliminary studies, and of Northwest Mettech Corporation and the Natural Sciences and Engineering Research Council of Canada for more recent work.
Muller: Material Science Forum, Vol. 426-432 (2003), p. 2539-2544 #8 #9 CuO-SDC mixed powders Samarium Cerium Oxide - Ce0.8Sm0.2 O1.9 Copper - Cu Copper oxide CuO Graphite C

Study On Continuous Casting Of Steel By Sizes Ardelean Erika1, a, *, Ardelean Marius2, b, Drăgoi Florin3, c , Popa Erika4, d 1,2,3,4 Faculty Engineering of Hunedoara, Polytechnic University of Timisoara, 5 Revolutiei Street, Hunedoara, postal code 331128, Romania a, *erika.ardelean@fih.upt.ro; bmarius.ardelean@fih.upt.ro; cflorin.dragoi@fih.upt.ro, derika.popa@fih.upt.ro Keywords: steel continuous cast, semi-finished products sizes, quality, technological parameters Abstract.
References [1] Xing Juan Wang, Li Guang Zhu, Ran Liu, Present situation and development perspective of soft-contact electromagnetic continuous casting technology, Advanced Materials Research, vol. 295-297, July 2011, pp.56-59; [2] Erika Ardelean, Teodor Hepuţ, Marius Ardelean, Research concerning the obtaining from industrial wastes of a cover powder used in steel continuous casting, Advanced Materials Research, vol. 23, October 2007, pp.329-332; [3] Joon Zang Chung, Improvements and innovations in the continuous casting process al POSCO, Materials Science Forum, vol.561-565, October 2007, pp.3-4; [4] Hong Pan, Guo Rong Wu, Zhi Qianq Li, Study on quality control technology for square/round billet in Panzhihua Steel, Advanced Materials Research, vol. 396-398, November 2011, pp.1138-1144; [5] Zi Bing Hou, Guo Guanq Chenq, Influence of casting speed on solidification process and solidification structure of continuously cast bloom, Advanced Materials Research, vol. 402, November 2011,

The implanted samples were characterized by SXRCT at Beamline 1-BM at the Advanced Photon Source (APS), Argonne National Laboratory.
The information, data, or work presented herein was funded in part by the Advanced Research Projects Agency-Energy (ARPA-E), U.S.
DE[1]SC0012704 This research used resources of the Advanced Photon Source, a U.S.
The Joint Photon Sciences Institute at SBU provided partial support for travel and subsistence for access to Advanced Photon Source.
Barbot, Strain Measurements on Nitrogen Implanted 4H-SiC, Materials Science Forum (2011)., 679–680, 185–188

Lider: Advanced Materials Research.
Garanin: Advanced Materials Research, Vol. 880, 134 (2014)
Li et al.: Materials Science and Engineering: A. 466 (2007), pp. 156–159
Lider: Advanced Materials Research.740 (2013), pp. 690-693
Kansy: Materials Science Forum. 666 (2010), pp. 138-141

Experimental and numerical investigations of TBC behaviour after aging, subjected to tension and bending Tomasz Sadowski1, a, Przemysław Golewski1,b 1Faculty of Civil Engineering and Architecture, Lublin University of Technology, Nadbystrzycka 38, 20-618 Lublin, Poland asadowski.t@gmail.com, bpgolewski@gmail.com Keywords: thermal barrier coating system, brittle cracking, thermal aging.
Advanced ceramic materials made of 2 phases are good examples for modern applications [1-3].
The obtained experimental results allow to perform advanced numerical modelling in the Abaqus including 3 different degradation processes.
Different level of advanced damage description was used as Fig. 8 shows.
The best results are achieved for the most advanced description, which takes into account both the damage of the TC and the BC (brittle cracking) and further - delamination caused by the growth of the TGO layer (cohesive surface).

Muhamad8,d 1, 2,3,4,5 Advanced Materials Research Centre (AMREC), SIRIM Berhad, 6Faculty of Mechanical, University of Technology Malaysia (UTM) 7Faculty of Dentistry, University of Malaya (UM) 8Herbal Medicine Research Centre (HMRC), Institute of Medical Research (IMR) arosdi@sirim.my , brafiq@fkm.utm.my , cnhayaty@um.edu.my , dshamsul@imr.gov.my Keywords: binder system, solvent extraction, debinding, sintering and in-vitro cytotoxicity test Abstract.
Acknowledgement This work partly was supported by Techno Fund Grant of Ministry of Science, Technology and Innovation (MOSTI) and Advanced Manufacturing Research Institute (AMRI), Advanced industrial Science and Technology (AIST), Japan.
Liu et. al, (2005), “Design of Powder Metallurgy Titanium Alloy and Composites”, Materials Science and Engineering, A 418 (2006) 25-35
Qazi (2005), “Titanium Alloy for Biomedical Application”, Materials Science and Engineering, C to be published
Muhamad (2009)., “Development of Macroporous Calcium Phosphate Scaffold via Microwave Rapid Drying”, Material Science and Engineering C 29: 1732-1740  __________________________ 5th Forum on New Materials Montecatini Terme, Italy June 13-18, 2010