Enhanced Tribological Performance of CVD Diamond Films Enabled by Using Graphene Layers as Solid Lubricant

Su Lin Chen; Bin Shen; Fang Hong Sun

doi:10.4028/www.scientific.net/AMR.1136.573

Paper Titles

Study on Mechanical Properties of Single-Crystal Silicon Carbide by Nanoindentation
p.549

Wear Mechanisms in Grinding of PCBN
p.555

Improving Tool Wear Resistance in Inconel 718 Cutting by Considering Surface Microstructures of CBN Cutting Tool
p.561

Effect of Carbide Orientation on Sliding Wear Behaviour of High Chromium Cast Iron
p.567

Enhanced Tribological Performance of CVD Diamond Films Enabled by Using Graphene Layers as Solid Lubricant
p.573

Wide Range and Accurate Measurement of Wafer Thickness Gauge Using Optical Spectral Analyzer
p.581

Measurement of the Temperature Distribution at the Tool-Chip Interface by Using a Cutting Tool with Seven Pairs of Built-In Micro Cu/Ni Thermocouples
p.586

In-Process Monitoring of the Machining State in Superfinishing by Measuring the Dynamic Machining Forces
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Experimental Study of the Causes for Shape Error of a Large Workpiece Machined by Surface Grinding
p.597

HomeAdvanced Materials ResearchAdvanced Materials Research Vol. 1136Enhanced Tribological Performance of CVD Diamond...

Enhanced Tribological Performance of CVD Diamond Films Enabled by Using Graphene Layers as Solid Lubricant

Abstract:

The present study reports the influence of graphene layers on the tribological performance of CVD diamond films when they are used as the solid lubricants. Friction tests are conducted on a ball-on-plate friction tester, where the stainless steel is used as the counterpart material. The CVD diamond film sample is a typical microcrystalline diamond (MCD) coating which is deposited on a flat tungsten carbide substrate using the hot filament chemical vapor deposition method (HFCVD). Besides the MCD sample, a polished MCD film (pMCD) and a polished tungsten carbide (pWC) are also adopted in frictional tests, aiming at illustrating the influence of the surface morphology, as well as the physical property, of the sample on the lubricative effect of graphene layers. The experimental results show that graphene layers can effectively reduce the coefficient of friction (COF), regardless of the samples. The MCD sample presents the lowest stable COF, which is 0.13, in dry sliding period when the graphene flakes are sparyed on the sliding interface; while the pMCD and pWC samples exhibit slightly higher COFs, which are 0.16 and 0.18, respectively. Comparatively, the COFs of these three samples obtained in dry sliding process without graphene are 0.20, 0.25 and 0.64. In additon, the MCD sample exhibits a much longer stable dry slidng process which is more than 5000 cycles. Comparatively, the other two tribo-pairs only exhibit a stable low-COF dry sliding period for around 2000 cycles. The reduction of COF could be attributed to the graphene flakes adhered on the sliding interface. It forms a layer of solid lubricative film with extremely low shear strength and significantly decreases the interactions between two contacted surfaces. The rugged surface of the MCD film provides sufficient clogging locations for graphene flakes, which allows the generated lubricative film enduring a long sliding duration. It can be arrived from this study that the tribological properties of the MCD film could be enhanced by simply adoping graphene layers as a solid lubricant. Furthermore, an improved performance of a variety of MCD coated cutting tools or mechanical components could be expected when they are utilized with graphene layers.

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Periodical:

Advanced Materials Research (Volume 1136)

Pages:

573-578

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.1136.573

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Online since:

January 2016

Authors:

Su Lin Chen, Bin Shen*, Fang Hong Sun

Keywords:

Diamond Coating, Friction, Graphene Layers, Surface Morphology

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References

[1] Tomé MA, Fernandes AJS, Oliveira FJ, Silva RF, Carrapichano JM. High performance sealing with CVD diamond self-mated rings, Diamond and Related Materials. 2005; 14: 617-621.

DOI: 10.1016/j.diamond.2004.12.053

Google Scholar

[2] Heaney PJ, Sumant AV, Torres CD, Carpick RW, Pfefferkorn FE. Diamond coatings for micro end mills: Enabling the dry machining of aluminum at the micro-scale, Diamond and Related Materials. 2008; 17: 223-233.

DOI: 10.1016/j.diamond.2007.12.009

Google Scholar

[3] Shen B, Sun F. Deposition and friction properties of ultra-smooth composite diamond films on Co-cemented tungsten carbide substrates, Diamond and Related Materials. 2009; 18: 238-243.

DOI: 10.1016/j.diamond.2008.10.053

Google Scholar

[4] Berman D, Erdemir A, Sumant AV. Few layer graphene to reduce wear and friction on sliding steel surfaces, Carbon. 2013; 54: 454-459.

DOI: 10.1016/j.carbon.2012.11.061

Google Scholar

[5] Berman D, Erdemir A, Sumant AV. Reduced wear and friction enabled by graphene layers on sliding steel surfaces in dry nitrogen, Carbon. 2013; 59: 167-175.

DOI: 10.1016/j.carbon.2013.03.006

Google Scholar

[6] Won M-S, Penkov OV, Kim D-E. Durability and degradation mechanism of graphene coatings deposited on Cu substrates under dry contact sliding, Carbon. 2013; 54: 472-481.

DOI: 10.1016/j.carbon.2012.12.007

Google Scholar

[7] Liu Y, Wang X, Pan G, Luo J. A comparative study between graphene oxide and diamond nanoparticles as water-based lubricating additives, Science China Technological Sciences. 2012; 56: 152-157.

DOI: 10.1007/s11431-012-5026-z

Google Scholar

[8] Chen SL, Shen B, Sun FH. Tribo-Map of CVD Diamond Film Sliding against Silicon Nitride in Air, Key Engineering Materials. 2013; 589-590: 405-410.

DOI: 10.4028/www.scientific.net/kem.589-590.405

Google Scholar