Thin-film amorphous carbon prepared by plasma chemical deposition processes

El-Hossary, F. M.

January 1986

No description available.

530.41

Semiconductor carbon films

Structure and properties of diamond-like carbon

Godwin, Paul D.

January 1997

No description available.

530.41

Amorphous carbon films

Properties of diamondlike carbon and nitrogen containing diamondlike carbon films

Shiao, Jeansong

January 1993

No description available.

diamondlike

carbon

nitrogen

carbon films

Structural Morphology And Electrical Transport In Boron Doped Amorphous Conducting Carbon Films

Vishwakarma, Prakash Nath

12 1900

No description available.

Carbon Films - Electrical Properties

Amorphous Conducting Carbon Films

Amorphous Conducting Carbon

Boron Doping

Amorphous Carbon Films

Amorphous Carbon

Materials Science

Deposition and characterisation of amorphous hydrogenated carbon films

Wächter, Rolf

January 1999

No description available.

667.9

Fabrication and properties of diamond-like carbon films in discharge plasmas

Rybachuk, Maksym

January 2007

This thesis presents theoretical and experimental study of properties of amorphous diamond-like carbon (DLC) coatings synthesised using discharge plasma methods. There were two objectives in this study. The first objective was to investigate the formation mechanism of hydrogenated DLC films (a-C:H) in an open hydrocarbon plasma source. The inductively coupled plasma (ICP) reactor was used to synthesise the films and the formation of sp2 and sp3 hybridised phases and the combination of these phases in the ICP plasma environment was studied. It was found that for a-C:H films with narrow distribution of the sp3 content the mechanical properties are determined by the degree of disorder of the sp2 fraction. The relationship between the sp3 content in fabricated films and hardness and Young's modulus was established. Raman and multi-wavelength (Vis – UV range) Raman spectroscopy was primarily used together with other suitable analytical methods to examine a-C:H films and it was found that films fabricated at higher ion energies displayed higher degree of clustering and bonding disorder than films produced at lower ion energies. All as fabricated a-C:H films were also found contain basic π-conjugated polymer inclusions as of trans-polyacetylene. The Raman results also reveal that the magnitude of Rayleigh scattered light is related to the relative density of the films, a feature that can be useful for monitoring film growth in-situ. The use of X-ray photoelectron spectroscopy (XPS) as a suitable method for measuring the sp3 content of the bulk DLC was also established. The second objective was to develop a fabrication technique that would allow fabrication of DLC films using graphite target sputtering with a single focused ion beam source and producing films with medium-high sp3 content. This research was motivated by the industrial partner of the project Laserdyne Pty Ltd that required a simple DLC deposition apparatus to be integrated into a standard, stand alone, optical thin film deposition chamber. Such technique was developed on the basis of a conventional ion beam target sputtering. In our experiments hydrogen-free DLC films with medium sp3 content were produced using a single, Kaufmann type ion source operated at low energies. The fabrication technique, denoted a reactive ion beam sputter deposition (RIBSD), was based on sputtering a graphite target at low incident angles and positioning the substrate at the grazing angles to the incoming ions, thus the incident ions (Ar and Xe ions were used) were simultaneously bombarding the target and the growing film. The effect of angle of incidence of an ion beam to the target and to the substrate in creating the sp3 content in DLC was investigated. It was found that the infringement bombardment of the substrate was not favourable for DLC growth as it essentially provided for a secondary re-sputtering process. Quality DLC films with approximately 40 % of the sp3 content were fabricated at the optimal angle of the ion flux to the target of 30º and to the substrate of 0º (parallel to the ion bema axis). The increased ion energy contributed to structural changes in DLC from predominantly sp2 graphitic like bonding to tetrahedral sp3 bonding arrangement.

The mechanical properties of diamond-like carbon films

Heidger, Susan Lynn

January 1993

No description available.

mechanical properties

diamond-like carbon films

Annealing of diamond and diamondlike carbon films: An ion beam analysis study

Zorman, Christian Aaron

January 1994

No description available.

Preparation, properties, and structure of hydrogenated amorphous carbon films

Chen, Hsiung

January 1990

No description available.

Physics, Condensed Matter

Ion beam analysis of diffusion in diamondlike carbon films

Chaffee, Kevin Paul

January 1991

No description available.

Physics, Condensed Matter

Ion beam analysis

diffusion

diamondlike carbon films