Surface Properties of Hard Fluorinated Amorphous Carbon Films Deposited by Pulsed-DC Discharges

• Autores: Miguel Rubio Roy
• Directores de la Tesis: Ricardo Molina Mansilla (dir. tes.), Enric Bertran Serra (dir. tes.)
• Lectura: En la Universitat de Barcelona ( España ) en 2010
• Idioma: catalán
• Tribunal Calificador de la Tesis: Fausto Sanz Carrasco (presid.), Carles Corbella Roca (secret.), Agustín Rodríguez González-Elipe (voc.)
• Materias:
  • Física
    • Física de fluidos
      • Física de plasmas
    • Física del estado sólido
      • Superficies
      • Tribología
• Enlaces
  • Tesis en acceso abierto en:  TDX  Dipòsit Digital de la UB 
• Resumen

  • New Generation Lithographic (NGL) techniques have been recently investigated in order to overcome the limitations of the long-used UV lithography. Several techniques have been proposed during the last decades, but the continued improvement of UV lithography rendered them useful only for a limited number of applications. More recently, nanoimprint lithography (NIL), invented in the nineties, has been considered as the new NGL due to its extreme simplicity and high resolution. Thermal NIL consists in the deformation of a thermoplastic under pressure and temperature by a nanostructured mold, while UV-NIL consists in the polymerization by UV light of a monomer at room temperature and under a lower pressure than Thermal NIL. One of the main problems of this technique is mold-polymer separation after the process. This problem is especially important for UV-NIL, because the working treatments for Thermal NIL degrade with UV light. In order to assess this problem, thin diamond-like amorphous carbon films (DLC) have been proposed as an alternative to existing treatments for their low chemical reactivity and the possibility to incorporate other chemical elements to further reduce their surface energy. Amorphous carbon exists in different forms, depending on how it is grown. Its mechanical properties range from polymer or graphite-like to almost as resistant as diamond. Besides the excellent mechanical properties of DLC (high hardness, elasticity and wear resistance, and low dry friction), amorphous carbon has also been found useful in applications requiring inert and/or biocompatible surfaces. The project DPI2007-61349 of the Science and Innovation Department of Spain, named “Amorphous carbon molds for micro and nanoimprint of polymeric surfaces”, aims to study the effect of the incorporation of different elements in DLC films for the improvement of NIL molds. This thesis has focused on a series of objectives of this project: - Design and construction of a very high vacuum reactor for deposition processes and ionic etch - Incorporation of fluorine to amorphous carbon films and subseqüent characterization by different surface, mechanical and tribological techniques, as well as spectroscopy for the characterization of the plasma used for the process. - Set up and optimization of a deep ion etch technique with ion beam for the production of molds. - The use of different lithographic techniques oriented to the production in large scale of nanometric patterns. - The exploration of mold coating to increase its durability and antisticking properties in nanoimprint processes. The incorporation of fluorine in DLC films has demonstrated to be useful in the improvement of the properties of NIL molds, because it avoids the use of the current surface treatments, which in addition to being less durable, can react with polymers in presence of UV light. In this thesis, the influence of fluorine incorporation in the films has been studied. Fluorinated amorphous carbon films have been deposited by pulsed-DC plasma enhanced chemical vapor deposition, by progressively replacing methane by trifluoromethane. The experimental device used for deposition has been designed and built to allow a number of multiple processes in the same reactor. The results of the study demonstrate the feasibility of this technique, of easy industrial implementation, for the deposition of this type of coatings. The characterization of both the active species in the plasma and the groups incorporated into the deposited films has helped to understand the process of fluorine incorporation, as well as the change in the surface properties that it entails.