DLC

Diamond like carbon (DLC) coated surfaces find widespread usage in modern industry. For instance, they are used as abrasion protection on engine components subject to heavy wear, and they increase the wear resistance of various materials. FISCHER offers advanced technology for the analysis of even the finest DLC coatings.

DLC

Application notes

Nanoindentation on wear-resistant DLC coatings applied to engine components

In order to reduce emissions in combustion engines without sacrificing performance, manufacturers are continually working to improve the ability of the moving parts (e.g. camshafts, piston rings and gears) to resist abrasion and reduce friction. Coating them with DLC (diamond-like carbon) is just such an optimization. DLC coatings are not only very hard but also feature a certain toughness – which are two of the critical parameters that must be monitored during the coating process. 

Composed primarily of amorphous diamond and amorphous graphite, DLC coatings serve first and foremost as protection against wear and tear but they also minimize friction. Due to their dark colour and the miniscule size of the indentation, determining their hardness by optically measuring the indenter impression is almost impossible and therefore unreliable.

A more accurate method for testing DLC coatings is nanoindentation, during which the force and displacement are continuously measured during both the loading and unloading phases. From these data, one can calculate the hardness and other quality-determining characteristics, such as the modulus of indentation. This method also prevents the substrate material from exerting any influence on the measurement results.

In this example, the measurement results of a 3 µm thick DLC layer are presented, as determined using the FISCHERSCOPE® HM2000. The Martens hardness (HM) takes the plastic and elastic deformation of the sample into account. The modulus of indentation (EIT), however, also allows conclusions to be drawn regarding the elastic behaviour. The values for penetration hardness (HIT) and the resultant converted Vickers hardness (HV) indicate the plastic properties of the samples.

DLC

coating

HM

N/mm²

EIT/(1-vs^2)

GPa

HIT

N/mm²

HV

X

8442.98

173.71

19398.17

1833.13

s

785.22

15.89

2320.85

219.32

V/%

9.3

9.15

11.96

11.96

Fig.1: Martens hardness (HM) and other parameters of the DLC coating. The table shows mean value, standard deviation und coefficient of variation of 12 measurements; the graph shows the depth-dependent profile. 

The standard deviations and coefficients of variation illustrate the accuracy with which these quality-related parameters can be determined, even on rough samples with thin coatings. But the FISCHERSCOPE® HM2000 also makes it simple to take these highly sophisticated measurements:

  • Extremely fast sample preparation
  • Short measuring times
  • High depth resolution
  • Minimal, thus negligible, device compliance

When it is utterly crucial to determine the mechanical properties of DLC coatings with speed, accuracy and precision, the FISCHERSCOPE® HM2000 is indispensable. For further details, please contact your local FISCHER representative anytime.

Your contact to FISCHER

Fischer Technology Inc.
Windsor/United States

Contact directly
Phone: (860) 683-0781
E-Mail: info@fischer-technology.com
Online contact form