Access the full text.
Sign up today, get DeepDyve free for 14 days.
A. Ghosh, Samir Das, J. Biswas, H. Tripathi, G. Banerjee (2000)
The effect of ZnO addition on the densification and properties of magnesium aluminate spinelCeramics International, 26
R. Sarkar, Samir Das, G. Banerjee (2003)
Effect of additives on the densification of reaction sintered and presynthesised spinelsCeramics International, 29
Shaowei Zhang, W. Lee (2004)
Spinel-Containing Refractories
R Sarkar (2010)
Refractory applications of magnesium aluminate spinelInterceram Refractories, 1
D. Bray (1985)
Toxicity of chromium compounds formed in refractoriesAmerican Ceramic Society Bulletin, 64
G. Rani, N. Ayachit (2015)
Low temperature synthesis of MgAl2O4 Spinel through sol-gel technique and its characterizationCanadian Journal of Physics, 93
R. Sarkar, S. Sahoo (2014)
Effect of raw materials on formation and densification of magnesium aluminate spinelCeramics International, 40
I. Ganesh (2013)
A review on magnesium aluminate (MgAl2O4) spinel: synthesis, processing and applicationsInternational Materials Reviews, 58
Taehyung Kim, Donghyun Kim, Shinhoo Kang (2014)
Effect of additives on the sintering of MgAl2O4Journal of Alloys and Compounds, 587
(1995)
Magnesia-spinel brick containing MgO rich spinel for steel refining ladle
Li-Zhai Pei, W. Yin, Ji-Fen Wang, Jun Chen, Chuan-Gang Fan, Qian-Feng Zhang (2010)
Low temperature synthesis of magnesium oxide and spinel powders by a sol-gel processMaterials Research-ibero-american Journal of Materials, 13
S. Uzunova, B. Banov, A. Momchilov, S. Vassilev, T. Stankulov, I. Uzunov (2005)
A low external temperature method for synthesis of active electrode materials for Li batteries – Part A: Synthesis of pure manganese spinelJournal of Applied Electrochemistry, 35
R. Pati, P. Pramanik (2004)
Low‐Temperature Chemical Synthesis of Nanocrystalline MgAl2O4 Spinel PowderJournal of the American Ceramic Society, 83
Ching-Jui Ting, Hong-Yang Lu (1999)
Defect reactions and the controlling mechanism in the sintering of magnesium aluminate spinelJournal of the American Ceramic Society, 82
K. Rozenburg, I. Reimanis, H. Kleebe, R. Cook (2007)
Chemical Interaction Between LiF and MgAl2O4 Spinel During SinteringJournal of the American Ceramic Society, 90
M. Patterson, Jenni Caiazza, D. Roy (2000)
Transparent spinel development, 4102
M. Posarac, A. Devecerski, T. Volkov-Husović, B. Matović, D. Minic (2009)
The Effect of Y2O3 Addition on Thermal Shock Behavior of Magnesium Aluminate SpinelScience of Sintering, 41
V. Singh, R. Sinha (1997)
Low temperature synthesis of spinel (MgAl2O4)Materials Letters, 31
R. Lodha, T. Troczynski, G. Oprea (2008)
Role of Oxide Additives in the Synthesis and Sintering of Magnesium Aluminate Spinel, 57
R Dal Maschio, B Fabbri, C Fiori (1988)
Industrial applications of refractories containing magnesium aluminate spinelInd Ceram(Italy), 8
I. Ganesh, S. Bhattacharjee, B. Saha, Roy Johnson, Y. Mahajan (2001)
A new sintering aid for magnesium aluminate spinelCeramics International, 27
R. Sarkar, S. Mukherjee, A. Ghosh (2008)
Effect of AlF3 on spinel formationIndustrial Ceramics, 28
G. Gonsalves, A. Duarte, P. Brant (1993)
Magnesia-spinel brick for cement rotary kilnsAmerican Ceramic Society Bulletin, 72
R. Sarkar, G. Bannerjee (2000)
Effect of addition of TiO2 on reaction sintered MgO–Al2O3 spinelsJournal of The European Ceramic Society, 20
P. Strobel, S. Rohs, F. Cras (1996)
Low-temperature synthesis and electrochemical lithium intercalation behaviour of defect Li-Mn-O spinel oxideJournal of Materials Chemistry, 6
(1986)
MA-spinel brick in glass furnace regenerators
(1995)
Effect of corundum/periclase sizes on expansion behaviour during synthesis of spinel, UNITECR’95 Congress
I. Ganesh, Kolli Teja, N. Thiyagarajan, Roy Johnson, B. Reddy (2005)
Formation and Densification Behavior of Magnesium Aluminate Spinel: The Influence of CaO and Moisture in the PrecursorsJournal of the American Ceramic Society, 88
R Sarkar (2011)
Additives for magnesium aluminate spinel: a reviewInterceram Refractories Manual, 1
Zhenwei Wang, Chun-Liang Chang, Chun-Liang Chang, Xinsheng Zhao, Weimin Qian, Xu Zhang, Zhong Xie, B. Hwang, Cheng Hu, Jun Shen, R. Hui (2009)
MgAl2O4-based humidity-sensing material for potential application in PEM fuel cellsJournal of Power Sources, 190
R. Sarkar, Tumpa Pal, G. Banerjee (2003)
Reaction sintering of magnesium aluminates: Effect of MgSO4
R. Lodha, A. Ghosh, B. Mukherjee, G. Agrawal (2006)
Zirconia-magnesium aluminate spinel composite - Improved ZrO2-MgAl2O4 composite was prepared by solid-state sintering.
R. Sarkar, H. Tripathi, A. Ghosh (2004)
Reaction sintering of different spinel compositions in the presence of Y2O3Materials Letters, 58
R. Sarkar, Samir Das, G. Banerjee (2002)
Effect of addition of Cr2O3 on the properties of reaction sintered MgO–Al2O3 spinelsJournal of The European Ceramic Society, 22
R. Marder, R. Chaim, G. Chevallier, C. Estournès (2011)
Effect of 1 wt% LiF additive on the densification of nanocrystalline Y2O3 ceramics by spark plasma sinteringJournal of The European Ceramic Society, 31
E. Segnit, A. Holland (1965)
The System MgO‐ZnO‐SiO2Journal of the American Ceramic Society, 48
Jianfeng Yang, Guo‐Jun Zhang, T. Ohji, K. Niihara (2000)
Effects of MgAl2O4-ZrO2 Addition on Sintering Behaviors and Mechanical Properties of Silicon Nitride CeramicsJournal of the Ceramic Society of Japan, 108
S. Hirai, Hideaki Murakami, H. Katayama (1991)
Effect of Additives on the Formation of MgAl 2 O 4 from MgO and Al 2 O 3Journal of The Japan Institute of Metals, 55
Commercially available fused magnesia and reactive alumina sources were used to develop stoichiometric magnesium aluminate spinel by solid-state reaction sintering technique. Zinc oxide was used as a sintering additive up to 2 wt%. The mixture was compacted using a uniaxial pressure of 150 MPa into pellets and bars. The pressed product was sintered in the temperature range of 1200 to 1600 °C. The dilatometric method was used to evaluate spinel formation with varying amount of zinc oxide. Phase analysis and density study were conducted to study the sintered products. The increase in additive content was found to improve the density and spinel formation in the composition. The dilatometric study showed that addition of zinc oxide reduced the spinel formation temperature and also increased shrinkage at higher temperatures, indicating better sintering. The microstructural study showed dense and compact nature of spinel in the presence of ZnO. One thousand six hundred degrees celsius sintered products were used to study flexural strength and thermal shock resistance.
Journal of the Australian Ceramic Society – Springer Journals
Published: Mar 16, 2017
Read and print from thousands of top scholarly journals.
Already have an account? Log in
Bookmark this article. You can see your Bookmarks on your DeepDyve Library.
To save an article, log in first, or sign up for a DeepDyve account if you don’t already have one.
Copy and paste the desired citation format or use the link below to download a file formatted for EndNote
Access the full text.
Sign up today, get DeepDyve free for 14 days.
All DeepDyve websites use cookies to improve your online experience. They were placed on your computer when you launched this website. You can change your cookie settings through your browser.