The tribological properties of nanometre carbon films prepared by plasma-based ion implantation at various implanting voltages

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AlN/Ti/TiN/DLC layers more than 1 µm thick have been prepared by plasma-based ion implantation sequentially with nitrogen/titanium/nitrogen and titanium/carbon on 2024 aluminium alloy. On the basis of our previous AlN/Ti/TiN/DLC layers, new AlN/Ti/TiN/DLC layers thicken by thickening the ‘TiN’ layer and the diamond-like (DLC) film. The structures of the new layers have been characterized by XPS, AFM and Raman spectrum. The new layers exhibit improved composition and structure gradients at the interface in addition to a thicker ‘TiN’ layer and DLC film than the previous ones and hence display significant improvements in surface hardness and tribological properties. Also, their surface topography, DLC structure, nanohardness, stress and tribological properties as a function of the DLC film thickness have been discussed.

Section: Hardness and Stresssupporting

confidence: 69%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Thick gradient layers prepared by plasma-based ion implantation on 2024 aluminium alloy

Liao¹,

Tian²,

Li³

et al. 2007

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“…Diamond-like carbon (DLC) films have widespread applications such as protective coatings in optical windows, magnetic storage discs, car parts, biomedical coatings, micro-electromechanical systems and devices therein [1] owing to their excellent tribological properties and other outstanding properties [2][3][4][5]. In particular, DLC films have served as a type of ideal lubricating and protective film due to unique antifriction and wear-resistance characteristics when normal oil lubrications and protective coatings are not suitable for some special fields where two or more mobile devices show micrometre, even nanometre, spaces and need smooth, compact, adhesive and wear-resistant thin solid films [6][7][8][9][10][11][12][13].…”

Section: Introductionmentioning

confidence: 99%

“…obtained by PBII are strongly dependent on the process parameters such as implanting voltage [9] and working gases [12]. As another prominent parameter, the implanting time, is proportional to the DLC film thickness and plays a dominant role in tribological properties [5], and hence is closely associated with the film applications.…”

Section: Introductionmentioning

confidence: 99%

Tribological performance of ultrathin diamond-like carbon films prepared by plasma-based ion implantation

Liao¹,

Li²,

Tian³

et al. 2008

Self Cite

Ultrathin diamond-like carbon (DLC) films with thicknesses of 5–60 nm have been prepared on Si by plasma-based ion implantation. Raman spectrum and x-ray photoelectron spectroscopy (XPS) show that these DLC films present high sp3/sp2 ratios. XPS also displays that each DLC film firmly adheres to the Si substrate owing to a C–Si transition layer. Atomic force microscopy shows that the DLC films are smooth and compact with average roughness (Ra) of about 0.25 nm. Sliding friction experiments reveal that these DLC films show significantly improved tribological performance. With increase of DLC film thickness, the sp3/sp2 ratio increases, the roughness decreases, the hardness increases, the adhesive wear lightens and thereby the tribological performance becomes enhanced. Also, the effects of the applied load and the reciprocating frequency on the tribological performance are discussed.

Synthesis and characterization of titanium-containing graphite-like carbon films with low internal stress and superior tribological properties

Wang¹,

Li²,

Li³

et al. 2012

Titanium-containing graphite-like carbon films were deposited on silicon substrates by an unbalanced magnetron sputtering system. The effect of titanium concentration on the film microstructure and properties was subsequently investigated by means of different characterization techniques. It is found that the current carbon films have a graphite-like structure with some fine titanium carbide particles dispersed in an amorphous carbon matrix. With increasing titanium concentration from 0 at% to ∼9.6 at%, the sp2 concentration in the film shows a slight increase, while the hardness of the carbon films decreases evidently when a small quantity of titanium (∼2.9 at%) is introduced into the film structure, but it does not suffer an obvious change with further increase in titanium concentration until the titanium concentration is up to ∼9.6 at%. The increased hardness of the film with a titanium concentration of about 9.6 at% is probably due to the formation of specified dimension titanium carbide crystals in the amorphous carbon matrix. All the current carbon films have low internal stress and rough surface, and the doping of titanium has little influence on their internal stress and root mean square roughness. The friction coefficient of the films decreases distinctly as the titanium concentration increases from 0 at% to ∼9.6 at%, but the wear rate does not increase evidently until the titanium concentration exceeds over ∼6.2 at% in air tests. The titanium-containing graphite-like carbon films show a stable friction coefficient and extremely low wear under oil lubricated conditions. The unique graphite-like structure, the high hardness and elastic modulus ratio (H/E) and the easy formation of a transfer film are mainly responsible for the superior tribological properties of the resulting titanium-containing graphite-like carbon films.