Inorganic nanoparticles synthesized by the novel oil-in-water microemulsion reaction method and their potential applications

• Autores: Kelly Lidia Pemartin
• Directores de la Tesis: Margarita Sáhchez Roca (dir. tes.), Carmen González Azón (dir. tes.), Concepcion Solans Marsa (dir. tes.)
• Lectura: En la Universitat de Barcelona ( España ) en 2013
• Idioma: inglés
• Tribunal Calificador de la Tesis: Joan Llorens Llacuna (presid.), Carlos Rodríguez Abreu (secret.), Cosima Stubenrauch (voc.)
• Materias:
  • Física
    • Química física
      • Química de interfases
      • Química del estado sólido
    • Unidades y constantes
  • Química
    • Química inorgánica
      • Estructura de los compuestos inorgánicos
• Enlaces
  • Tesis en acceso abierto en:  TDX  Dipòsit Digital de la UB 
• Resumen

  • The use of microemulsions as confined reaction media for nanoparticle synthesis presents various advantages compared to other methods. They offer a high control of nanoparticle size and often nanoparticles with crystalline structure and a high specific area are obtained directly during the synthesis, eliminating the need for calcination. Also, due to their thermodynamic stability, no energy input is needed for microemulsion formation; only a gentle agitation is sufficient to obtain microemulsions. In addition, simple equipment and mild conditions of temperature and pressure are employed. The traditional W/O microemulsion reaction method has been intensively studied. However, the use of W/O microemulsions has some drawbacks preventing their use in industrial applications. The most important drawback is the organic solvents used as the continuous phase, which are environmentally unfriendly. Also, they are cost ineffective. In order to overcome these drawbacks, our group has recently introduced the novel oil-in-water (O/W) microemulsion reaction method for inorganic nanoparticle synthesis. The advantage of using an aqueous continuous phase, the use of the organometallic precursors that can be loaded at comparable or higher concentration than the metallic salts in the traditional W/O microemulsions (promoting a higher nanoparticle yield), and the use of only one microemulsion (instead of two as in the traditional W/O method), indicate the promise of this novel method. This novel method consists in the use of organometallic precursors, dissolved in nanometer scale oil droplets of O/W microemulsions, and stabilized by a monolayer of hydrophilic surfactant. The precipitating agents, usually water-soluble, can be added directly or as aqueous solutions, without compromising microemulsion stability and droplet size; alternatively, if oil-soluble precipitating agents are available, then a two-microemulsions approach can be used. The main motivation for this development was that, to the best of our knowledge, there was a lack of methods in the literature employing O/W microemulsions in which the metallic precursors were dissolved (and confined) in the oil droplets. In addition, another strong motivation was that, from a practical and environmental point of view, the possibility of preparing inorganic nanoparticles using o/w microemulsions (as opposed to w/o microemulsions) could be highly advantageous, since the major (continuous) phase is water. Metal 2-ethylhexanoates have been used in the Oil-in-Water microemulsion reaction method as precursors of inorganic nanoparticles, mainly because these precursors were very soluble in hydrocarbons such as hexane or isooctane, which can be conveniently used as the oil phase in this approach. In addition, these type of precursors are available for a wide number of elements, they are inexpensive, air-stable (unlike alkoxide sol-gel precursors), and generally non-toxic. This type of precusors is often used for the synthesis of inorganic nanoparticles like metallic or metal oxides by thermal decomposition at temperatures as high as 200-300ºC, in polar organic solvents and generally under an inert atmosphere, or by pyrolysis at much higher temperatures. The various types of inorganic nanoparticles prepared in O/W microemulsion reaction method were selected on the basis of their specific characteristics for several potential applications. Oxide nanoparticles containing Cerium, Copper and Zinc were prepared for their interest in catalysis. In addition, CuO and CeO2 nanoparticles were also prepared as reference materials in order to compare properly the characteristics of the obtained materials. Semi-conductors such as Zinc oxide, Zinc peroxide and Zinc Selenide were synthesized and their specific characteristics such as fluorescent, electrical and photocatalytic properties were assessed. Finally, magnetic Mn-Zn ferrites nanoparticles with potential applications in fields such as biomedicine and thermoelectrics were prepared and their magnetic properties were assessed. Formation and stability of nanoparticle dispersions were also studied in order to assess their potential application in the biomedicine field.