An overview on the microstructure and mechanical properties of sintered aluminum-based composites

Authors

Shoba Chintada Dept of Mechanical Engineering, GITAM (Deemed to be University), Visakhapatnam, 530045, INDIA
Siva Prasad Dora Dept of Mechanical Engineering, GITAM (Deemed to be University), Visakhapatnam, 530045, INDIA
Dorathi Kare Dept of Mechanical Engineering, Sri Vasavi Engineering College, Tadepalligudem, A.P. INDIA and Research Scholar, Dept of Mechanical Engineering, GITAM (Deemed to be University), Visakhapatnam, 530045, INDIA

DOI:

https://doi.org/10.30544/687

Keywords:

sintering; composites; powder metallurgy; aluminum.

Abstract

Sintered composites have revolutionized as a thermal treatment to consolidate a wide range of engineering materials where the transition of powders takes place thermally in a thermodynamical equilibrium state with a decrease in free surface energy in materials owing to their specific capability. Sintering aids in providing effective bonding between the reinforced powder particles. However, the inadequate understanding of the sintering mechanism may limit the practical application of a few materials such as aluminum metal matrix composites. In addition to the rapid growth of various sintering related technologies, researchers need attention to highlight the structural barriers and forecast the emerging demands while dealing with such composites. A review report is made in this paper regarding the sintering mechanisms and sintering techniques. Common sintering techniques such as traditional, microwave assisted, hot pressing, hot isostatic sintering, and spark plasma sintering are identified and discussed here. As a result, the key challenges in sintering aluminium metal matrix composites that can affect sintering parameters are investigated. From the review, spark plasma is identified to attain densified and pore-free green composites and, microwave sintering is the best technique for achieving uniform microstructure in powder metallurgy samples.

References

W.C. Harrigan Jr: Mater Sci Eng A, 244 (1998) 75-79.

Zhigang Zak Fang: Sintering of Advanced Materials, Wood head publishing, 2010.

F. V. Lenel: Powder Metallurgy, Metal Powder Industries Federation, 1980, 593.

Y. Huang, Q. Ouyang, D. Zhang, J. Zhu, R Li, H. Yu: Acta Metall Sin, 27 (2014) 775-786.

C. Deng, D. Wang, X. Zhang, A. Li: Mater Sci Eng A, 444 (2007) 138-145.

D. S. Prasad, N.S. Ebenezer, Ch. Shoba: Trans Indian Inst Met, 70 (2017) 2601-2607.

D. S. Prasad and Ch. Shoba: Mater Sci Eng, 599 (2014) 25-27.

D. S. Prasad, N.S. Ebenezer, Ch. Shoba, P.S. Rao: Mater Res Express, 5 (2018) 1-11.

D. S. Prasad, N.S. Ebenezer, Ch. Shoba, P. Raju, P.S. Rao: Silicon, 11 (2019) 2025-2032.

V. S. S. Venkatesh, Ashish B. Deoghare: Adv Mater Process Technol, (2021)

D. S. Prasad, Ch. Shoba, T.R. Palukuri, P.S. Rao: Eng Sci Technol an Int. J, 23 (2020) 1285-1290.

D. S. Prasad, Ch. Shoba; Silicon, 11 (2019) 2907-2918.

Ch. Shoba, D. S. Prasad, A. Sucharita, M. Abishek, M.S. Koundinya; Mater. Today: Proc, 5 (2018) 16565-16574.

Ch. Shoba, D. S. Prasad, Dorathi Kare, Parameswara Rao Venkata Doddi: Met Powder Rep, 76 (2021) 32-39.

Alok Bhadauria, Lavish K. Singh, Sapan Kumar Nayak, Tapas Laha: Mater Charact, 168 (2020) 1-15.

Alok Bhadauria, Lavish K.Singh, Tapas Laha; Mater Sci Eng, 749 (2019) 14-26.

Ya.I. Matvienko, S.S. Polishchuk, A.D. Rud, O.Yu. Popov, S.A. Demchenkov, O.M. Fesenko: Mater Chem Phys, 254 (2020) 1-12.

Morteza Tayebi, Mohamad Jozdani, Mehdi Mirhadi: J Alloys Compd, 809 (2019) 1-7.

C. Padmavathi, A. Upadhyaya, D. Agrawal: Mater. Chem Phys, 130 (2011) 449-457.

M. A. Himyan, M. Penchal Reddy, F. Ubaid, R. A. Shakoor, A. M. A. Mohamed: Scanning, 2018 (2018) 1-8.

M. Penchal Reddy, R.A. Shakoor, Gururaj Parande, Vyasaraj Manakari, F. Ubaid, A.M.A. Mohamed, Manoj Gupta: Prog Nat Sci, 27 (2017) 606-614.

M. Khan, R. Ud Din, M. Abdul Basit, A. Wadood, S. Wilayat Husain, S. Akhtar, R. Elizabeth Aune: Mater Chem Phys, 271 (2021) 1-19.

Zhao-Hui Zhang, Fu-Chi Wang, Jie Luo, Shu-Kui Lee, Lu Wang: Mater Sci Eng A, 527 (2010) 7235-7240.

R. Abedinzadeh, S. M. Safavi, F. Karimzadeh: J Mech Sci Technol, 30 (2016) 1967-1972.

X. Gao, H. Yue, E. Guo, H. Zhang, X. Lin, L. Yao: Mater Des, 94 (2016) 54-60.

H.S. Chen: J Alloy Compd, 730 (2018) 342-351.

Penchal Reddy Matli, Rana Abdul Shakoor, Adel Mohamed Amer Mohamed, Manoj Gupta: Metals, 6 (2016)1-19.

K.N. Manjunath, G.B. Krishnappa: Mater Today-Proc, 5 (2018) 3019-3026.

C. Padmavathi, A. Upadhyaya and D. Agrawal: Bull Mater Sci, 35 (5) (2012) 823-832.

S. Singh, D. Gupta, V. Jain: Proc Inst Mech Eng, Part B J Eng Manuf, 230 (2015) 603-617.

S. Lin, W. Xiong: Adv Powder Technol, 23 (2012) 419-425.

K. Rajkumar, S. Aravindan: J Mater Proc Technol, 209 (200) 5601-5605.

C. Leonelli, P. Veronesi, L. Denti, A. Gatto, L. Iuliano: J Mater Proc Technol, 205 (2008) 489-496.

K. Saitou: Scr Mater, 54 (2006) 875-879.

J. Walkiewicz, G. Kazonich, S. McGill: Miner Metall Process, 5 (1988) 39-42.

Morteza Oghbaei and Omid Mirzaee: J Alloy Compd, 494 (2010)175-189.

R. M. German: Sintering Theory and Practice, Wiley, New York, 1996, 568.

S. Takayama, Y. Saiton, M. Sato, T. Nagasaka, T. Muroga, Y. Ninomiya, In: Proceedings of the 9th conference on microwave and high frequency heating, (2003) 369-372.

Adnan Khan, W. Motasem, Abdelrazeq, Manohar Reddy Mattli, M. Moinuddin Yusuf, Abdullah Alashraf, Penchal Reddy Matli and R. A. Shakoor: Crystals, MDPI, 10 (2020) 1-12.

Ehsan Ghasali, MasoudAlizadeh, TouradjEbadzadeh, Amir hossein Pakseresht, Ali Rahbari: J Mater Res Technol, 4 (2015) 411-415.

Penchal Reddy Matli, Ubaid Fareeha, Rana Abdul Shakoor, Adel Mohamed Amer Mohamed: J Mater Res Technol, 7 (2018) 165-172.

S. Chintada, S.P. Dora, D. Kare: Silicon (2021) 1-12.

Penchal Reddy Matli, Rana Abdul Shakoor, Adel Mohamed Amer Mohamed: Intech, (2018), 23-43.

H.M. Wang, J.Q. Liu, G.R. Li, F. Tang, Y.W. Yan, L.P. Gao, Y.T. Zhao: J Mater Res Technol, 13 (2021) 1509 -1520.

Penchal Reddy Matli, Ubaid Fareeha, Rana Abdul Shakoor, Adel Mohamed Amer Mohamed: J Mater Res Technol, 7 (2018) 165-172.

P. Fulay, D. Askeland: Essentials of materials science and engineering. Cengage Learning, Toronto, 2009.

J. Burke: Ultrafine-grain ceramics, Springer Science & Business Media, New York, 2012.

C. Martínez, F. Briones, P. Rojas, S. Ordoñez, C. Aguilar, D. Guzmán: MRS Adv, 2 (50) (2017) 2831-2836.

H. Zhang, C. Xu, W. Xiao, K. Ameyama, C. Ma: Mater Sci Eng A, 658 (2016) 8-15.

Zhanqiu Tan, Zhiqiang Li, Genlian Fan, Xizhou Kai, Gang Ji, Lanting Zhang, Di Zhang: Compos B Eng, 47 (2013) 173-180.

J. J. Conway: Powder Metal Technol Appl, (2004) 49-53.

C.L. Qiu, M.M. Attallah, X.H. Wu, P. Andrews: Mater Sci Eng A, 564 (2013) 176-185.

G. Ran, J. Zhou, Q.G. Wang: J. Alloys Compd, 421 (2006) 80-86.

S. Yan, S. Dai, X. Zhang, C. Yang, Q. Hong, J. Chen: Mater Sci Eng A, 612 (2014) 440-444.

K. Essa, R. Khan, H. Hassanin H, M.M. Attallah, R. Reed: Int J Adv Manuf Technol, 83 (2016) 1835-1845.

Saud M. Almotairy, A. Fadavi Boostani, M. Hassani, D. Wei, Z.Y. Jiang: J Mater Res Technol, 9 (2020) 1151-1161.

Ismaila Kayode Aliyu, Nouari Saheb, Syed Fida Hassan, Nasser Al-Aqeeli: Metals 5 (2015) 70-83.

S. Bathula, R.C. Anandani, A. Dhar, A.K. Srivastava: Mater Sci Eng A, 545 (2012) 97-102.

K. Mizuuchi, K. Knoue, Y. Agari, M. Sugioka, M. Tanaka, T. Takeuchi, J.I. Tani, M. Kawahara, Y. Makino, Mikio: Microelectron Reliability, 54 (2014) 2463-2470.

D. Garbiec, M. Jurczyk: Composite Theory and Practice, 13 (2013) 255-259.

J.H. Yu, C.B. Wang, Q. Shen, L.M. Zhang: Mater Des, 41 (2012) 198-202.

A. Azarniya, Azarniya Amir, S. Sovizi, H.R.M. Hosseini, T. Varol, A. Kawasaki: Progr Mater Sci, 90 (2017) 276-324.

K. Nishikata, A. Kimura, T. Shiina, A. Ota, M. Tanase, K. Tsuchiya: In: Powder Metallurgy World Congress & Exhibition, (2012) 14-18.

J. M. Ju, G. Wang, K. H. Sim: J Alloys Comp, 704 (2017) 585-592.

A. Bisht, M. Srivastava, R.M. Kumar, I. Lahiri, D. Lahiri: Mater Sci Eng A, 695 (2017) 20-28.

D. Tiwari, B. Basu, K. Biswas: Ceram Int, 35 (2009) 699-708.

W. Chen, U. Anselmi-Tamburini, J. Garay, J. Groza, Z.A. Munir: Mater Sci Eng A, 394 (2005) 132-138.

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Published

2022-03-31

How to Cite

Chintada, Shoba, Siva Prasad Dora, and Dorathi Kare. 2022. “An Overview on the Microstructure and Mechanical Properties of Sintered Aluminum-Based Composites”. Metallurgical and Materials Engineering 28 (1):1-16. https://doi.org/10.30544/687.

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Issue

Vol. 28 No. 1 (2022): Composite materials - novelties in manufacturing and application

Section

Composite materials - novelties in manufacturing and application

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Copyright (c) 2022 Shoba Chintada, Siva Prasad Dora, Dorathi Kare

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