References
- Kar S, Sahu BB, Kousaka H, et al. Study of the effect of normal load on friction coefficient and wear properties of CNx thin films. AIP Adv. 2020;10(6):065214.
- Reddy IS, Kaliveeran V. Dry sliding friction and wear of Al 6061 and Al 6082 alloys under different normal loads. Mater Today Proc. 2020;27(3):2631–2634.
- Zhou Y, Zhu H, Zhang W, et al. Influence of surface roughness on the friction property of textured surface. Adv Mech Eng. 2015;7(2):1–9.
- Chowdhury MA, Khalil MK, Nuruzzaman DM, et al. The effect of sliding speed and normal load on friction and wear property of aluminum. Int J Mech Mechatron Eng. 2011;11(01):45–49.
- Mishra T, Rooij M, Schipper DJ. The effect of asperity geometry on the wear behaviour in sliding of an elliptical asperity. Wear. 2021;470–471:203615.
- Ding S, Xu J, Liu P, et al. Geometric influence on friction and wear performance of cast iron with a micro-dimpled surface. Results in Eng. 2021;9:100211.
- Pauschitz A, Roy M, Franek F. Mechanisms of sliding wear of metals and alloys at elevated temperatures. Tribol Int. 2008;41(7):584–602.
- Kennedy FE, Lu Y, Baker I. Contact temperatures and their influence on wear during pin-on-disk tribotesting. Tribol Int. 2015;82(Part B):534–542.
- Chen Z, He X, Xiao C, et al. Effect of humidity on friction and wear-A critical review. Lubricants. 2018;6(3):74.
- Wahyudi M, Ismail R, Jamari J. Friction and wear analysis of UHMWPE material using pin-on-disc tester with lubricant and non-lubricant. J Phys. 2020;1569(3):032057.
- Trivedi HK, V BD. Effect of lubricating oil on tribological behaviour in pin on disc test rig. Tribol Ind. 2017;39(1):90–99.
- Chaturvedi V, Pandel U, Sharma A. Effect of mechanical vibrations on the wear behavior of AZ91 Mg alloy. Mat sci eng. 2018;314:012030.
- Choudhury ND, Saha N, Bhaumik S, et al. Production and evaluation of physicochemical, rheological, and tribological properties of Cucurbita pepo L. seed oil. Biomass Convers Biorefin. 2021;1–14. DOI:10.1007/s13399-020-01236-5
- Husnawan M, Saifullah MG, Masjuki HH. Development of friction force model for mineral oil basestock containing palm olein and antiwear additive. Tribol Int. 2007;40(1):74–81.
- Liaquat AM, Kalam MA, Masjuki HH, et al. Potential emissions reduction in road transport sector using biofuel in developing countries. Atmos Environ. 2010;44(32):3869–3877.
- Nuraliza N, Syahrullail S, Faizal MH. Tribological properties of aluminum lubricated with palm olein at different load using pin-on-disk machine. J Tribol. 2016;9:45–59.
- Jayadas NH, Nair KP. Coconut oil as base oil for industrial lubricants-evaluation and modification of thermal, oxidative and low temperature properties. Tribol Int. 2006;39(9):873–878.
- Syahrullail S, Kamitani S, Shakirin A. Performance of vegetable oil as lubricant in extreme pressure condition. Procedia Eng. 2013;68:172–177.
- Singh Y, Sharma A, Singh NK, et al. Moringa Oleifera: bio based lubricant development from a novel feedstock for tribological characterization. Adv Mater Process Technol. 2020;8(1):1–13.
- Sajeeb A, Rajendrakumar PK. Comparative evaluation of lubricant properties of biodegradable blend of coconut and mustard oil. J Clean Prod. 2019;240:118255.
- Bikash B, Choudhury ND, Bora DK, et al. Physicochemical assessment of pumpkin (L.) seed oil as a viable feedstock for biodiesel production. Conference Proceedings of the Second International Conference on Recent Advances in Bioenergy Research, SSS-NIBE, Kapurthala, India, 2018;19–28.
- Lestari B, Meiyanto E. A review: the emerging nutraceutical potential of pumpkin seeds. Indones J Cancer Chemoprevention. 2018;9(2):92–101.
- Shaban A, Sahu RP. Pumpkin seed oil: an alternative medicine. Int J Pharmacogn Phytochem Res. 2017;9(2):1–8.
- Aleksandar V, Aleksandar R. Tribological behaviour of al-based Mmcs and their application in automotive industry. Tribol Ind. 2004;26(3–4):31–38.
- Baruah M, Borah A. On the enhancement of wear resistance of Al-Mg-Si alloy via micro-alloying Sn. Sādhanā. 2021;46(129):1–9.
- Habib A, Biswas S, Siddique AH, et al. Nutritional and lipid composition analysis of pumpkin seed (Cucurbita maxima Linn.). J Nutr Sci. 2015;05(04):374–379. DOI:10.4172/2155-9600.1000374
- Gul M, Masjuki HH, Kalam MA, et al. A review: role of fatty acids composition in characterizing potential feedstock for sustainable green lubricants by advance transesterification process and its global as well as Pakistani prospective. BioEnergy Res. 2019;13(1):1–22.
- Souza MCD, Wiesner HM, Kuche Y, et al. Influence of the fatty acid profile on the lubricating film formation in micro-milling process on 7050-T7451 aluminum alloy. Int J Adv Manuf Technol. 2020;106(1):233–241.
- Shi H, Du S, Sun C, et al. Behavior of wear debris and its action mechanism on the tribological properties of Medium-Carbon steel with magnetic field. Materials. 2018;12(1):45–64.
- Mozgovoy S, Hardell J, Deng L, et al. Effect of temperature on friction and wear of prehardened tool steel during sliding against 22mnb5 steel. Tribol Mater Surf Interfaces. 2014;8(2):65–73.
- Nuruzzaman DM, Chowdhury MA. Effect of load and sliding Velocity on Friction Coefficient of Aluminum sliding against different pin materials. Am J Mater Sci. 2012;2(1):26–31.
- Feng K, Shao T. The evolution mechanism of tribo-oxide layer during high temperature dry sliding wear for nickel-based superalloy. Wear. 2021;476:203747.
- Pearson SR, Shipway PH, Abere JO, et al. The effect of temperature on wear and friction of a high strength steel in fretting. Wear. 2013;303(1–2):622–631.