Coating-assisted laser micromachining of UHMWPE: Thermal control and microchannel optimisation using PDMS and PAA

Ojo Kurdi; Eko Hadi; Ari Santosa; Muhammad Hadi; Rifky Ismail; Oktarina Heriyani; Ojo Kurdi; Eko Hadi; Ari Santosa; Muhammad Hadi; Rifky Ismail; Oktarina Heriyani

doi:10.3934/matersci.2025036

AIMS Materials Science

2025, Volume 12, Issue 4: 845-860. doi: 10.3934/matersci.2025036

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Coating-assisted laser micromachining of UHMWPE: Thermal control and microchannel optimisation using PDMS and PAA

1.
Department of Mechanical Engineering, Faculty of Engineering, Diponegoro University, Jl. Prof Sudharto, Tembalang, Semarang, Central Java 50275, Indonesia
2.
Department of Naval Architecture, Faculty of Engineering, Diponegoro University, Jl. Prof Sudharto, Tembalang, Semarang, Central Java 50275, Indonesia
3.
Department of Mechanical Engineering, Faculty of Industrial and Informatics Technology, Muhammadiyah University, Prof. Dr. HAMKA, Jakarta Timur 13830, DKI Jakarta, Indonesia

Received: 12 May 2025 Revised: 30 July 2025 Accepted: 12 August 2025 Published: 28 August 2025

Ultra-high molecular weight polyethylene (UHMWPE) is established as a material of choice in tribological and biomedical applications because of its superior impact resilience, low coefficient of friction, and outstanding wear resistance. Nevertheless, its intrinsic low thermal conductivity poses significant challenges during laser surface texture (LST), manifesting as thermal anomalies, including surface bulging and geometric distortion. In this study, we addressed these limitations by implementing a thermal regulation framework that integrates polymeric coatings, polyacrylic acid (PAA) and polydimethylsiloxane (PDMS), to mitigate thermally induced deformation in diode laser micromachining. A uniform coating thickness of 150 µm was applied through a controlled screen-printing protocol. The samples were then textured using a 520 nm, 4 W diode laser in a matrix of focal distances (22 to 54 mm) and scanning speeds (2 to 10 mm/s). Quantitative characterization of the resulting microchannels was conducted using confocal microscopy and profilometry, emphasizing dimensional metrics such as depth, width, and height of the curve. PDMS-coated substrates consistently demonstrated superior thermal stability and geometric accuracy among all configurations. At the optimal settings identified (38 mm focal distance, 4 mm/s scanning speed), microchannels exhibited a depth of 43.2 µm, a width of 35.2 µm and a minimal bulge height of 10 µm. This investigation contributes a scalable and cost-efficient approach to the advancing laser-based micromachining of UHMWPE, particularly in applications requiring precise surface architectures. The demonstrated integration of laser parameter optimization with polymer-based thermal modulation offers significant implications for designing and fabricating high-performance components in seawater-lubricated tribosystems and microfluidic biomedical platforms.
- UHMWPE,
- laser texturing,
- PDMS coating,
- thermal damage,
- microchannels,
- tribology
Citation: Ojo Kurdi, Eko Hadi, Ari Santosa, Muhammad Hadi, Rifky Ismail, Oktarina Heriyani. Coating-assisted laser micromachining of UHMWPE: Thermal control and microchannel optimisation using PDMS and PAA[J]. AIMS Materials Science, 2025, 12(4): 845-860. doi: 10.3934/matersci.2025036

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Abstract

Ultra-high molecular weight polyethylene (UHMWPE) is established as a material of choice in tribological and biomedical applications because of its superior impact resilience, low coefficient of friction, and outstanding wear resistance. Nevertheless, its intrinsic low thermal conductivity poses significant challenges during laser surface texture (LST), manifesting as thermal anomalies, including surface bulging and geometric distortion. In this study, we addressed these limitations by implementing a thermal regulation framework that integrates polymeric coatings, polyacrylic acid (PAA) and polydimethylsiloxane (PDMS), to mitigate thermally induced deformation in diode laser micromachining. A uniform coating thickness of 150 µm was applied through a controlled screen-printing protocol. The samples were then textured using a 520 nm, 4 W diode laser in a matrix of focal distances (22 to 54 mm) and scanning speeds (2 to 10 mm/s). Quantitative characterization of the resulting microchannels was conducted using confocal microscopy and profilometry, emphasizing dimensional metrics such as depth, width, and height of the curve. PDMS-coated substrates consistently demonstrated superior thermal stability and geometric accuracy among all configurations. At the optimal settings identified (38 mm focal distance, 4 mm/s scanning speed), microchannels exhibited a depth of 43.2 µm, a width of 35.2 µm and a minimal bulge height of 10 µm. This investigation contributes a scalable and cost-efficient approach to the advancing laser-based micromachining of UHMWPE, particularly in applications requiring precise surface architectures. The demonstrated integration of laser parameter optimization with polymer-based thermal modulation offers significant implications for designing and fabricating high-performance components in seawater-lubricated tribosystems and microfluidic biomedical platforms.

References

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