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Online since: October 2010
Authors: Gerard L. Vignoles, William Ros, Ivan Szelengowicz, Christianne Mulat, Christian Germain, Marc Donias
Ceramic Matrix Composites (CMCs)[1] and Carbon-Fibre Reinforced Carbons (CFRCs)[ 2,3] are thermostructural materials, already in use in extremely demanding technologies like aerospace, and are promising candidates for new applications in the fields of civil aircraft propulsion[4] and nuclear power engineering [5], among others.
The author should indicate on the checklist if he wishes to have them printed in full color and make the necessary payments in advance.
Forum Vol. 83-87 (1992), p. 119 [2] M.A.
Mishing, in: Diffusion Processes in Advanced Technological Materials, edtied by D.
Witten, in: Proceedings of the IEEE 13th Symposium on Fusion Engineering Vol. 2 (1990), p. 947
The author should indicate on the checklist if he wishes to have them printed in full color and make the necessary payments in advance.
Forum Vol. 83-87 (1992), p. 119 [2] M.A.
Mishing, in: Diffusion Processes in Advanced Technological Materials, edtied by D.
Witten, in: Proceedings of the IEEE 13th Symposium on Fusion Engineering Vol. 2 (1990), p. 947
Online since: November 2025
Authors: Oleksandr Kondratenko, Kseniia Umerenkova, Volodymyr Koloskov, Olha Lytvynenko, Hanna Koloskova, Vitaliy Borysenko
Engineering Innovations. 7 (2023) 51–59
Key Engineering Materials. 935 (2023) 85–97
Gas Science and Engineering. 131 (2024) 205484
Chemical Engineering Journal. 495 (2024) 153521
Chemical Engineering Journal Advances. 14 (2023) 100490
Key Engineering Materials. 935 (2023) 85–97
Gas Science and Engineering. 131 (2024) 205484
Chemical Engineering Journal. 495 (2024) 153521
Chemical Engineering Journal Advances. 14 (2023) 100490
Online since: May 2014
Authors: Keyna O'Reilly, Sundaram Kumar, Sam Agarwal
In-situ Al3Nb formation in liquid Al by Nb particle addition
Sundaram Kumar1,a, Sam Agarwal2,b and Keyna O’Reilly3,c
1,2,3Department of Materials, University of Oxford, Parks Road, Oxford, OX1 3PH, United Kingdom and The EPSRC Centre for Innovative Manufacturing in Liquid Metal Engineering.
The overall thickness of this layer is purely governed by the growth rate of the advancing layer front and dissolution of layer in contact with unsaturated melt.
Forum, 217-222 (1996) 359-364
The overall thickness of this layer is purely governed by the growth rate of the advancing layer front and dissolution of layer in contact with unsaturated melt.
Forum, 217-222 (1996) 359-364
Online since: October 2006
Authors: Syo Matsumura, Kazuhiro Yasuda
Radiation Damage Effects in Insulators for Fusion Reactors:
Microstructure Evolution in MgO-Al2O3 System Oxide Crystals
Kazuhiro Yasuda1, a and Syo Matsumura1
1
Department of Applied Quantum Physics and Nuclear Engineering, Kyushu University
Hakozaki, Fukuoka 812-8581, Japan
a
yasudak@nucl.kyushu-u.ac.jp
Keywords: fusion materials, oxide insulating ceramics, displacement damage, electronic excitation,
electric field, dislocation loops, transmission electron microscopy
Abstract.
In order to advance the above discussion further, the stability of dislocation loops were investigated in detail at higher temperature [11,12].
Matsumura: Defect and Diffusion Forum Vol. 206&207 (2002), p. 53 [13] K.
In order to advance the above discussion further, the stability of dislocation loops were investigated in detail at higher temperature [11,12].
Matsumura: Defect and Diffusion Forum Vol. 206&207 (2002), p. 53 [13] K.
Online since: January 2005
Authors: Ferenc Tranta, Jenő Sólyom, Valéria Mertinger, Erzsebet Nagy
The X-ray measurements were done by a Bruker Advance D8
diffractometer using Co Kα radiation.
[3] E.Nagy, V.Mertinger, F.Tranta, J.Sólyom, article in press Materials Science Engineering A [4] E.Nagy-V.Mertinger-F.Tranta-J.Sólyom, Mat.
Forum Vols. 414-415. (2003) pp.281-288
[3] E.Nagy, V.Mertinger, F.Tranta, J.Sólyom, article in press Materials Science Engineering A [4] E.Nagy-V.Mertinger-F.Tranta-J.Sólyom, Mat.
Forum Vols. 414-415. (2003) pp.281-288
Online since: August 2020
Authors: Mashuri Mashuri, Yanurita Dwi Hapsari, Bintoro Anang Subagyo, Yoyok Cahyono, Zaenal Arifin, Linda Silvia, Amilia Amilia, Lana Awathifi, Heru Sukamto, Mariyanto Mariyanto, Malik Anjelh Baqiya, Sri Yani Purwaningsih, Mochammad Zainuri, Sudarsono Sudarsono
It needs to be investigated in advances because most previous studies have been conducted using limestone to obtain CaCO3.
Urquhard, Civil Engineering Handbook, 4th ed., Mc Graw.
Forum 18 (1994) 135-155.
Urquhard, Civil Engineering Handbook, 4th ed., Mc Graw.
Forum 18 (1994) 135-155.
Online since: March 2008
Authors: Nathan Klingbeil, Jeremy Daily, Craig Baudendistel
A Dissipated Energy Approach to Fatigue Crack Growth in Ductile
Solids and Layered Materials
Nathan Klingbeil1,a, Jeremy Daily2,b, Craig Baudendistel1,c
1Wright State University, Department of Mechanical and Materials Engineering, 3640
Colonel Glenn Hwy., Dayton, OH 45435, USA.
2The University of Tulsa, Department of Mechanical Engineering, 600 S.
F33615-02-D2299-0022, and by the Department of Mechanical & Materials Engineering at Wright State University.
Ellyin, "A fatigue crack propagation model," Engineering Fracture Mechanics, vol. 20, pp. 695-704, 1984
Birol, "What happens to the energy input during fatigue crack propagation," Materials Science and Engineering, vol.
Fatemi, "Mixed mode fatigue crack growth: a literature survey," Engineering Fracture Mechanics, vol. 55, no. 6, pp. 969-990, 1996
F33615-02-D2299-0022, and by the Department of Mechanical & Materials Engineering at Wright State University.
Ellyin, "A fatigue crack propagation model," Engineering Fracture Mechanics, vol. 20, pp. 695-704, 1984
Birol, "What happens to the energy input during fatigue crack propagation," Materials Science and Engineering, vol.
Fatemi, "Mixed mode fatigue crack growth: a literature survey," Engineering Fracture Mechanics, vol. 55, no. 6, pp. 969-990, 1996
Online since: July 2011
Authors: Xue Chen Duan, Xiao Qi Liu, Ming Hui Shen, Jie Nan Chen
To make up for those disadvantages, and expand the application scope of red phosphorous, our country adopts the advanced Microencapsulation, and microencapsulates the red phosphorous.
But presently, compared with foreign advanced product, domestic magnesium hydroxide flame retarder has many defects.
The industry needs to make greater efforts to develop advanced technology and reduce production cost and product price.
Summary About the author: LIU Xiaoqi, female, born in Dec.1972, Doctoral candidate and lecturer in School of Resources Processing and Bio-engineering of Central South University(410083), major in mineral processing and material chemistry.
Chemical Engineering and Equipment, 2009, p114-115 [32] WANG Xiaoying, BI Chengliang, LI Lili and ZHANG Baogui: The Research Development of the New Environment-friendly Flame Retarder.
But presently, compared with foreign advanced product, domestic magnesium hydroxide flame retarder has many defects.
The industry needs to make greater efforts to develop advanced technology and reduce production cost and product price.
Summary About the author: LIU Xiaoqi, female, born in Dec.1972, Doctoral candidate and lecturer in School of Resources Processing and Bio-engineering of Central South University(410083), major in mineral processing and material chemistry.
Chemical Engineering and Equipment, 2009, p114-115 [32] WANG Xiaoying, BI Chengliang, LI Lili and ZHANG Baogui: The Research Development of the New Environment-friendly Flame Retarder.
Online since: May 2018
Authors: Hilda Chikwanda, L. Mahlatji
Bhadeshia, Practical ODS Alloys, Materials Science and Engineering A, 223 (1997)64-77
[2] Suryanarayana C.
Marcel Dekker, New York Chap 13 [5] Koch CC (1993) Nano Struct Mater 2:109 [6] Benjamin JS (1970) Metall Trans 1:2943 [7] Koch CC, Cavin OB, McKamey CG, Scarbrough JO (1983) Appl Phys Lett 43:1017 [8] C Suryanarayana et al., The science and technology of mechanical alloying, Materials Science and Engineering A304-306 (2001) 151-158 [9] C Suryanarayana, Recent developments in mechanical alloys, Rev.
Scientific American, 234, 40-49 [12] R M Davis, and CC Koch, Mechanical alloying of brittle components: Silicon and germanium, Scripta Metallurgica, Volume 21, Issue 3, March 1987, Pages 305-310 [13] C Suryanarayana, Mechanical alloying and Milling, Progress in Material Science 46 (2001) 1-184 [14] C Suryanarayana, Mechanical Alloying of Advanced materials, Powder Materials: Current Research and Industrial Practices III, MS&T 2003 [15] JR Groza, In: Non-equilibrium processing of materials, ed by C Suryanarayana (Pergamon, Oxford, Uk, 1999) p. 347 [16] J.R Groza, In: Nanostructured Materials: Processing, Properties, and Applications, ed.
Forum (1992) 16, 19
In Advances in Powder Metallurgy (1991) (Eds.: L.
Marcel Dekker, New York Chap 13 [5] Koch CC (1993) Nano Struct Mater 2:109 [6] Benjamin JS (1970) Metall Trans 1:2943 [7] Koch CC, Cavin OB, McKamey CG, Scarbrough JO (1983) Appl Phys Lett 43:1017 [8] C Suryanarayana et al., The science and technology of mechanical alloying, Materials Science and Engineering A304-306 (2001) 151-158 [9] C Suryanarayana, Recent developments in mechanical alloys, Rev.
Scientific American, 234, 40-49 [12] R M Davis, and CC Koch, Mechanical alloying of brittle components: Silicon and germanium, Scripta Metallurgica, Volume 21, Issue 3, March 1987, Pages 305-310 [13] C Suryanarayana, Mechanical alloying and Milling, Progress in Material Science 46 (2001) 1-184 [14] C Suryanarayana, Mechanical Alloying of Advanced materials, Powder Materials: Current Research and Industrial Practices III, MS&T 2003 [15] JR Groza, In: Non-equilibrium processing of materials, ed by C Suryanarayana (Pergamon, Oxford, Uk, 1999) p. 347 [16] J.R Groza, In: Nanostructured Materials: Processing, Properties, and Applications, ed.
Forum (1992) 16, 19
In Advances in Powder Metallurgy (1991) (Eds.: L.
Online since: July 2015
Authors: Abdul Hadi, Junaidah Jai, Md Amin Hashim, Sakinah Mohd Yusof
Amin Hashimb,Junaidah Jaic and Abdul Hadid*
Faculty of Chemical Engineering, Universiti Teknologi MARA, 40000 Shah Alam, Malaysia
akeynayusof@gmail.com, baminhashim@salam.uitm.edu.my, cjunejai@salam.uitm.edu.my, dhadi9598@salam.uitm.edu.my
Keywords: Nanostructure, electrodeposition, lead-free solder, alloy.
Forum, vol. 297–301, pp. 169–179, Apr. 2010
Chan, “Microelectronics Reliability Research advances in nano-composite solders,” vol. 49, pp. 223–234, 2009
Forum, vol. 297–301, pp. 169–179, Apr. 2010
Chan, “Microelectronics Reliability Research advances in nano-composite solders,” vol. 49, pp. 223–234, 2009