REFERENCES
- Goodwin, F.E. and Ponikvar, A.L. (1989), Engineering Properties of Zinc Alloys, International Lead Zinc Research Organization: Durham, NC.
- Gervais, E., Levert, H., and Bess, M. (1980), “The Development of a Family of Zinc-Base Foundry Alloys,” Transactions of the American Foundrymen's Society, 88, pp 183–194.
- Murphy, S. and Savaşkan, T. (1984), “Comparative Wear Behaviour of Zn-Al-Based Alloys in an Automotive Engine Application,” Wear, 98, pp 151–161.
- Altorfer, K. (1982), “Zinc Alloys Compete with Bronze in Bearings and Bushings,” Metal Progress, 34, pp 29–31.
- Prasad, B., Patwardhan, A., and Yegneswaran, A. (1996), “Dry Sliding Wear Characteristics of Some Zinc–Aluminium Alloys: A Comparative Study with a Conventional Bearing Bronze at a Slow Speed,” Wear, 199, pp 142–151.
- Calayag, T. and Ferres, D. (1982), “High-Performance, High-Aluminum Zinc Alloys for Low-Speed Bearings and Bushings,” SAE Transactions, 91, pp 2241–2251.
- Zhu, Y., Torres-Villasenor, G., and Pina, C. (1994), “Complex Microstructural Changes in As-Cast Eutectoid Zn-Al Alloy,” Journal of Materials Science, 29, pp 1549–1552.
- Zhu, Y.H. and Goodwin, F.E. (1995), “Microstructures of Thermomechanically Treated Eutectoid Zn-Al Alloy (II),” Journal of Materials Research, 10, pp 1927–1932.
- Savaşkan, T. and Azaklı, Z. (2008), “An Investigation of Lubricated Friction and Wear Properties of Zn-40Al-2Cu-2Si Alloy in Comparison with SAE 65 Bearing Bronze,” Wear, 264, pp 920–928.
- Savaşkan, T. and Bican, O. (2005), “Effects of Silicon Content on the Microstructural Features and Mechanical and Sliding Wear Properties of Zn-40Al-2Cu-(0-5) Si Alloys,” Materials Science and Engineering A, 404, pp 259–269.
- Pürçek, G., Savaşkan, T., Küçükömeroğlu, T., and Murphy, S. (2002), “Dry Sliding Friction and Wear Properties of Zinc-Based Alloys,” Wear, 252, pp 894–901.
- Prasad, B.K. (2007), “Investigation into Sliding Wear Performance of Zinc-Based Alloy Reinforced with SiC Particles in Dry and Lubricated Conditions,” Wear, 262, pp 262–273.
- Savaşkan, T., Pürçek, G., and Murphy, S. (2002), “Sliding Wear of Cast Zinc-Based Alloy Bearings under Static and Dynamic Loading Conditions,” Wear, 252, pp 693–703.
- Prasad, B., Patwardhan, A., and Yegneswaran, A. (1997), “Dry Sliding Wear Response of a Modified Zinc-Based Alloy,” Materials Transactions, 38, pp 197–204.
- Prasad, B.K. (2000), “Effect of Microstructure on the Sliding Wear Performance of a Zn-Al-Ni Alloy,” Wear, 240, pp 100–112.
- Durman, M. and Murphy, S. (1991), “Precipitation of Metastable -Phase in a Hypereutectic Zinc–Aluminium Alloy Containing Copper,” Acta Metallurgica et Materialia, 39, pp 2235–2242.
- Murphy, S. and Yeung, C. (1999), “Early Stages of Phase Transformation in Quenched Zinc–Aluminum Based Alloys,” Journal of Materials Processing Technology, 94, pp 78–84.
- Hanna, M., Carter, J., and Rashid, M. (1997), “Sliding Wear and Friction Characteristics of Six Zn-Based Die-Casting Alloys,” Wear, 203, pp 11–21.
- Prasad, B.K., Yegneswaran, A., and Patwardhan, A. (1996), “Characterization of the Wear Response of a Modified Zinc-Based Alloy vis-a-vis a Conventional Zinc-Based Alloy and a Bearing Bronze at a High Sliding Speed,” Metallurgical and Materials Transactions A, 27, pp 3513–3523.
- Prasad, B.K. (1996), “Influence of Heat Treatment on the Physical, Mechanical and Tribological Properties of a Zinc-Based Alloy,” Zeitschrift für Metallkunde, 87, pp 226–232.
- Prasad, B.K., Patwardhan, A., and Yegneswaran, A. (1996), “Influence of Heat Treatment Parameters on the Microstructure and Properties of Some Zinc-Based Alloys,” Journal of Materials Science, 31, pp 6317–6324.
- Murphy, S. and Savaşkan, T. (1987), “Metallography of Zinc–25% Aluminium Based Alloys in the As-Cast and Aged Conditions,” Practical Metallography, 24, pp 204–221.
- Savaşkan, T. and Murphy, S. (1987), “Mechanical Properties and Lubricated Wear of Zn-25Al-Based Alloys,” Wear, 116, pp 211–224.
- Prasad, B.K. (1997), “Effects of Silicon Addition and Test Parameters on Sliding Wear Characteristics of Zinc-Based Alloy Containing 37.5% Aluminium,” Materials Transactions, 38, pp 701–706.
- Savaşkan, T. and Aydıner, A. (2004), “Effects of Silicon Content on the Mechanical and Tribological Properties of Monotectoid-Based Zinc–Aluminium–Silicon Alloys,” Wear, 257, pp 377–388.
- Savaşkan, T., Hekimoğlu, A.P., and Pürçek, G. (2004), “Effect of Copper Content on the Mechanical and Sliding Wear Properties of Monotectoid-Based Zinc–Aluminium–Copper Alloys,” Tribology International, 37, pp 45–50.
- Lee, P.P., Savaskan, T., and Laufer, E. (1987), “Wear Resistance and Microstructure of Zn-Al-Si and Zn-Al-Cu Alloys,” Wear, 117, pp 79–89.
- Avner, S.H. (1974), Introduction to Physical Metallurgy, McGraw-Hill Book Company: New York.
- Askeland, D.R. (1988), The Science and Engineering of Materials, S. I. edition, Boston, MA: VNR International.
- Savaşkan, T. and Bican, O. (2010), “Dry Sliding Friction and Wear Properties of Al-25Zn-3Cu-(0-5)Si Alloys in the As-Cast and Heat-Treated Conditions,” Tribology Letters, 40, pp 327–336.
- Rodriguez, J., Poza, P., Garrido, M., and Rico, A. (2007), “Dry Sliding Wear behaviour of Aluminium–Lithium Alloys Reinforced with SiC Particles,” Wear, 262, pp 292–300.
- Rameshkumar, T. and Rajendran, I. (2013), “Mechanical and Tribological Properties on Al-Sn-Si Alloy-Based Plain Bearing Material,” Tribology Transactions, 56(2), pp 268–274.
- Savaşkan, T., Pürçek, G., and Hekimoğlu, A. (2003), “Effect of Copper Content on the Mechanical and Tribological Properties of ZnAl27-Based Alloys,” Tribology Letters, 15, pp 257–263.
- Halling, J. (1974), Principles of Tribology, London: MacMillan.
- Erickson, R.C. (1982), “Effects of Mechanical Properties on the Wear Resistance of Journal Bearing Alloys,” ASLE Transactions, 25(3), pp 309–322.
- Kumar, P.S., Manisekar, K., Subramanian, E., and Narayanasamy, R. (2013), “Dry Sliding Friction and Wear Characteristics of Cu-Sn Alloy Containing Molybdenum Disulfide,” Tribology Transactions, 56(5), pp 857–866.
- Sun, Y. (2012), “Wear Behaviors of AA 6063 Aluminum Alloys Reinforced with in situ Al3Ti Particles,” Tribology Transactions, 55(2), pp 224–229.
- Prasad, B.K. (2005), “Sliding Wear Response of a Zinc-Based Alloy and Its Composite and Comparison with a Gray Cast Iron: Influence of External Lubrication and Microstructural Features,” Materials Science and Engineering A, 392, pp 427–439.
- Rice, S.L., Nowotny, H., and Wayne, S.F. (1981), “Characteristics of Metallic Subsurface Zones in Sliding and Impact Wear,” Wear, 74, pp 131–142.
- Akarca, S., Altenhof, W., and Alpas, A. (2007), “Subsurface Deformation and Damage Accumulation in Aluminum–Silicon Alloys Subjected to Sliding Contact,” Tribology International, 40, pp 735–747.