Publications
Export 61 results:
Sort by: Author Keyword Title Type [ Year
] Filters: Author is M. Chakraborty [Clear All Filters]
. MICROSTRUCTURAL EVOLUTION OF Al-Si BASED COMPOSITES REINFORCED WITH IN-SITU TiB2 PARTICLES. Submitted.
. Design of an Ideal Grain-Refiner Alloy for Al-7Si Alloy Using Artificial Neural Networks. Journal of materials engineering and performance. 2013:1–4.
. Recent Developments in Aluminium Alloy Reinforced Titanium Diboride in-situ Composites. Indian Foundry Journal. 2012;58.
. Effect of TiAl3 particles size and distribution on their settling and dissolution behaviour in aluminium. Journal of materials science. 2010;45:2921–2929.
. Settling behaviour of TiAl 3, TiB 2, TiC and AlB 2 particles in liquid Al during grain refinement. International Journal of Cast Metals Research. 2010;23:193–204.
. Al–Ti–C–Sr master alloy—A melt inoculant for simultaneous grain refinement and modification of hypoeutectic Al–Si alloys. Journal of Alloys and Compounds. 2009;480:L49–L51.
. Grain refinement response of LM25 alloy towards Al–Ti–C and Al–Ti–B grain refiners. Journal of Alloys and Compounds. 2009;472:112–120.
journal homepage: www. elsevier. com/locate/msea. Materials Science and Engineering A. 2009;506:196–197.
. Sliding wear behaviour of T6 treated A356–TiB 2 in-situ composites. Wear. 2009;266:865–872.
. Wear behaviour of near eutectic Al–Si alloy reinforced with in-situ TiB 2 particles. Materials Science and Engineering: A. 2009;506:27–33.
. Ageing behaviour of A356 alloy reinforced with in-situ formed TiB 2 particles. Materials Science and Engineering: A. 2008;489:220–226.
. Equal channel angular pressing of Al–5wt% TiB 2 in situ composite. Journal of Alloys and Compounds. 2008;459:239–243.
. Microstructural features of as-cast A356 alloy inoculated with Sr, Sb modifiers and Al–Ti–C grain refiner simultaneously. Materials Letters. 2008;62:273–275.
. Microstructure and the wear mechanism of grain-refined aluminum during dry sliding against steel disc. Wear. 2008;264:638–647.
. On the modification and segregation behavior of Sb in Al–7Si alloy during solidification. Materials Letters. 2008;62:2013–2016.
. Tensile and wear behaviour of in situ Al–7Si/TiB 2 particulate composites. Wear. 2008;265:134–142.
. Tensile and wear behaviour of in-situ Al-7Si-TiB2 particulate composites. Wear. 2008;265:134-142.
. A comparative study of mechanical properties and wear behaviour of Al-4Cu-TiB 2 and Al-4Cu-TiC in-situ composites. Transactions of the Indian Institute of Metals. 2007;60:201–205.
. Effect of TiB 2 particles on sliding wear behaviour of Al–4Cu alloy. Wear. 2007;262:160–166.
Inoue, A. 146. Materials Science and Engineering A. 2007;465:295–296.
. Role of combined addition of Sr and Sb on the microstructure and mechanical properties of cast A356 alloy. Transactions of the Indian Institute of Metals. 2007;60:257–261.
. Wear behaviour of Al-Si alloys reinforced with in-situ formed TiB2 particles. TRANSACTIONS OF THE INDIAN INSTITUTE OF METALS. 2007;60:113–117.
. Development of Al–Ti–C grain refiners and study of their grain refining efficiency on Al and Al–7Si alloy. Journal of Alloys and compounds. 2005;396:143–150.
Haldar, A. 402 Han, MK 66 Haušild, P. 188 Hernandez, M.-A. 71. Materials Science and Engineering A. 2005;391:433–434.
. Improvement in tensile strength and load bearing capacity during dry wear of Al–7Si alloy by combined grain refinement and modification. Materials Science and Engineering: A. 2005;395:323–326.
. Poisoning and fading mechanism of grain refinement in Al-7Si alloy. Mater. Forum. 2005;29:387–393.
. Poisoning and fading phenomena in the grain refinement of Al and its alloys. TRANSACTIONS-INDIAN INSTITUTE OF METALS. 2005;58:661.
. Prediction of grain size of Al–7Si Alloy by neural networks. Materials Science and Engineering: A. 2005;391:131–140.
. A Comparison of the Grain Refining Efficiency of Al-5 Ti-0. 3 C with Other Grain Refiners in Al and Al-7 Si Alloy. Indian Foundry Journal. 2004;50:29–33.
. Effect of grain refinement on wear properties of Al and Al–7Si alloy. Wear. 2004;257:148–153.
. Effect of rolling on Al-5Ti binary master alloy (sponge route) and its grain refining performance in aluminium. Journal of Metallurgy and Materials Science. 2004;46:107–113.
. Effect of TiB 2 particles on aging response of Al–4Cu alloy. Materials Science and Engineering: A. 2004;386:296–300.
. Influence of thermo-mechanical processing of Al–5Ti–1B master alloy on its grain refining efficiency. Materials Science and Engineering: A. 2004;364:75–83.
. Effect of Al-1Ti-3B, Sr and Mg on the grain refining and modification behaviour of LM-6 alloy. INDIAN FOUNDRY JOURNAL. 2003;49:24–29.
. Effect of Sb, Bi, Cd and Sr additions on the microstructure and wear properties of Al-7 Si alloy. Transactions of the Indian Institute of Metals. 2003.
. Effect of Ti addition on the grain refining potency of TiB 2 in Al and Al-7 Si alloys. Transactions of the Indian Institute of Metals. 2003.
. Influence of thermo-mechanical treatment of Al–5Ti master alloy on its grain refining performance on aluminium. Materials Science and Engineering: A. 2003;351:237–243.
. Microstructural and mechanical characteristics of in situ Al-5 TiC metal matrix composites. Transactions of the Indian Institute of Metals. 2003.
. A neural network approach to grain refinement in Al-7 Si alloys by Al-3 B and Al-3 Ti binary master alloys. Transactions of the Indian Institute of Metals. 2003.
. Grain refinement of aluminium and its alloys by heterogeneous nucleation and alloying. International Materials Reviews. 2002;47:3–29.
. Thermo-mechanical treatment of Al-5Ti-1B and Al-5Ti master alloy on its grain refining performance on aluminium. Journal of Metallurgy and Materials Science. 2002;44:109–125.
. Trends in melt treatment of aluminium and its alloys. Indian Foundry Journal. 2002;48:19–27.
Abd El-Maksoud, S. 207. Materials Science and Engineering. 2001;301:259.
. Development of in-situ Al-TiB 2 metal matrix composites. Journal of Metallurgy and Materials Science. 2001;43:93–101.
. Effect of Al-5Ti-1B Grain Refiner on some Hypereutectic Al-Si Alloys. Indian Foundry Journal. 2001;47:13–17.
. Effect of hot rolling and heat treatment of Al–5Ti–1B master alloy on the grain refining efficiency of aluminium. Materials Science and Engineering: A. 2001;301:180–186.
. Assessment of Grain Refinement and Modification of Eutectic Al-Si Alloys by Computer Aided Cooling Curve Analysis (CA-CCA). Indian Foundry Journal. 2000;46:35–40.
. Development of an efficient grain refiner for Al–7Si alloy. Materials Science and Engineering: A. 2000;280:58–61.
. Development of an efficient grain refiner for Al–7Si alloy and its modification with strontium. Materials Science and Engineering: A. 2000;283:94–104.
. Influence of silicon and magnesium on grain refinement in aluminium alloys. Materials science and technology. 1999;15:986–992.
. Manufacture of Al–Ti–B master alloys by the reaction of complex halide salts with molten aluminium. Journal of materials processing technology. 1999;89:152–158.
. Role of zirconium and impurities in grain refinement of aluminium with Al-Ti-B. MATERIALS SCIENCE AND TECHNOLOGY-LONDON-. 1997;13:769–777.
. Role of zirconium and impurities in grain refinement of aluminium lNith AI-Ti-B. Materials science and technology. 1997;13:769–777.
. Influence of chromium and impurities on the grain-refining behavior of aluminum. Metallurgical and Materials Transactions A. 1996;27:791–800.
. Influence of chromium and impurities on the grain-refining behavior of aluminum. Metallurgical and Materials Transactions A. 1996;27:791–800.
. Reaction of fluoride salts with aluminium. Materials science and technology. 1996;12:766–770.
. INVESTIGATION OF THICK TIN PROTECTIVE COATINGS ON COPPER WITH THE AID OF X-RAY PHOTOELECTRON SPECTROSCOPY. Trans. Metal Finishing Assocn. India. 1994;3:78.