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Abstract

Ceramic coatings exhibit wear-resistant and damping characteristics that attenuate system vibrations, enhancing the overall surface performance of the system. This investigation involved a ceramic coating (Al₂O₃–40%TiO₂) deposition onto an SS 304 substrate through a thermally flame spraying process. The study encompassed the characterization of the surface morphology of the coated substrate using field emission scanning electron microscope and energy dispersive X-ray spectroscopy techniques. It was observed that the coating possesses a dense coating structure with fully melted regions and splat deposition and is uniformly distributed throughout the cross-section. The average measured microhardness surface roughness value was 812 HV and 2.55 µm, respectively. Furthermore, this study sought to experimentally determine the damping ratio for both the coated and uncoated substrates, and it aimed to evaluate their damping properties by analyzing the amplitude of the fast Fourier transform plot. The damping ratio for coated and uncoated substrates are 0.021316 and 0.016557 by the logarithmic decrement method, whereas 0.021174 and 0.016244 by the half-power bandwidth method, respectively. It was observed that coated material increases the damping ratio, increases the natural frequency, and ultimately increases the stiffness.

Keywords

Ceramic coating microstructure damping frequency response function

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References

Treviso

Van Genechten

Mundo

, et al. Damping in composite materials: properties and models. Compos B Eng 2015; 78: 144–152.

Al-Hababi

Cao

Saleh

, et al. A critical review of nonlinear damping identification in structural dynamics: methods, applications, and challenges. Sensors 2020; Vol 20: 7303.

Bonetti

Campari

Casagrande

, et al. Damping behavior of layered aluminium and aluminide coatings on AISI 316 austenitic steel. Coatings 2020; 10: 88.

Siengchin

. A review on lightweight materials for defence applications: present and future developments. Defence Technol 2023; 24: 1–17.

Izzuddin

Akın

Bekmezci

, et al. Evolving trends and advanced applications of engineering materials in contemporary aircraft: a review. J Sci Rep-A 2024; 58: 179–196.

Filipi

Hoffman

O’Donnell

, et al. Enhancing the efficiency benefit of thermal barrier coatings for homogeneous charge compression ignition engines through application of a low-k oxide. Int J Engine Res 2020; 22: 1906–1923.

Dong

Yuan

, et al. Effects of TiO₂ nano-particles on wear-resistance and vibration-reduction properties of a polymer for water-lubricated bearing. Wear 2023; 522: 204713.

Shaid Sujon

Islam

Nadimpalli

. Damping and sound absorption properties of polymer matrix composites: a review. Polym Test 2021; 104: 107388.

Gupta

. Friction and wear mechanism of polymers, their composites and nanocomposites. Tribol Polymers, Polymer Compos Polymer Nanocomp 2023: 51–117.

10.

Liu

Ding

Peng

, et al. Tribological properties of multilayer DLC/MoS₂ nanocomposite coatings on microtextured titanium alloy surfaces. Lubricants 2024; 12: 74.

11.

Fan

Meng

Yang

, et al. Experimental study of the effect of viscoelastic damping materials on noise and vibration reduction within railway vehicles. J Sound Vib 2009; 319: 58–76.

12.

Inozume

Aihara

. Damping ratio maximization in thickness direction using viscoelastic and structural materials based on constrained layer damping. Eng Optim 2022; 54: 539–551.

13.

Jin

Chen

Zhao

, et al. Preparation of a superior damping coating and study on vibration damping properties. SN Appl Sci 2023; 5: –8.

14.

Alva

Raja

. Dynamic characteristics of epoxy hybrid nanocomposites. J Reinf Plast Compos 2011; 30: 1857–1867.

15.

Zhou

, et al. Damping efficiency of the coating structure. Int J Solids Struct 2005; 42: 3045–3058.

16.

Khor

Chia

, et al. High temperature damping behavior of plasma sprayed NiCoCrAlY coatings. J Therm Spray Technol 2002; 11: 359–364.

17.

Min

Chen

, et al. Damping performance of mo-based coatings prepared by supersonic arc spraying. Surf Eng 2021; 37: 1388–1395.

18.

Xie

Chu

Peng

, et al. A mini review on coated pipes: Materials, manufacturing and anti-corrosion protection. Corros Eng, Sci Technol 2024. https://doi.org/10.1177/1478422X241278895.

19.

Tang

Yan

. A review on the damping properties of fiber reinforced polymer composites. J Ind Text 2018; 49: 693–721.

20.

Wang

Zhou

, et al. Nonlinear dissipative devices in structural vibration control: a review. J Sound Vib 2018; 423: 18–49.

21.

Koch

Johnson

Kumar

, et al. Pulsed laser deposition of hydroxyapatite thin films. Mater Sci Eng C 2007; 27: 484–494.

22.

Balestri

Brown

Kim

, et al. Adjustable vibration damper design for superconducting quarter wave resonators. 2025. https://doi.org/10.1177/10775463241312818.

23.

Sharma

Sundararajan

Gautam

. Identification of limiting damping mechanisms in a high quality factor hybrid resonator of space application gyroscope. Adv Space Res 2022; 69: 1662–1679.

24.

Tweten

Ballard

Mann

. Minimizing error in the logarithmic decrement method through uncertainty propagation. J Sound Vib 2014; 333: 2804–2811.

25.

Singh

Nanda

. Estimation of damping in layered welded structures with unequal thickness. Shock Vib 2012; 19: 1463–1475.

26.

Ansari

Kumar

. Experimental investigation of the static and dynamic damping behaviour of antifriction bearings. Nondestruct Test Eval 2024; 40: 453–474.

27.

Rani

Agrawal

Rastogi

. Vibration analysis for detecting failure mode and crack location in first stage gas turbine blade. J Mech Sci Technol 2019; 33: 1–10.

28.

Zhou

, et al. Damping efficiency of the coating structure. Int J Solids Struct 2005; 42: 3045–3058.

29.

Ansari

Kumar

Rastogi

. Dynamic behavior of aluminium matrix composite rotor on bearing vibration. Mater Today Proc 2022; 62: 233–238.

30.

Sharma

Rastogi

Agrawal

. Estimation and experimental validation of mean-field homogenised effective properties of composite. Exp Tech 2021; 45: 445–456.

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Investigating the characterization and damping effects in thermally sprayed Al 2 O 3 –40% TiO 2 ceramic coating

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