In order to achieve these goals, the Unit is designed to encompass three major integrated and interrelated directions (pillars) in modern materials research. These three pillars which provide a multidisciplinary research methodology to the study of Advanced Nanostructured Materials, and make the proposed Unit unique in the scientific and technological map of Cyprus are:
Computational and Simulations Materials Science: research within this activity will focus on modeling and design of advanced innovative materials for applied science and engineering applications, using a multiscale methodological approach spanning the entire spectrum from the atomistic to the macroscopic level.
Synthesis of Nanoengineered Materials: research will focus on the development and growth of nanostructured thin films with significant engineering applications including hard coatings, solid lubricants, wear-resistant layers for environmental protection, new coatings for solar energy applications, biocompatible coatings for medical applications.
Nanoscale Chracterization: research will concentrate on the determination, testing, characterization and nanoscale control of materials properties. Examples of techniques to be employed include nanoindentation, atomic force and scanning electron microscopy, X-ray diffraction, etc.
It should be noted that the synergistic approach between the three mentioned research directions is only found in a handful of materials research centers worldwide.
Philosophy
In order to achieve these goals, the Unit is designed to encompass three major integrated and interrelated directions (pillars) in modern materials research. These three pillars which provide a multidisciplinary research methodology to the study of Advanced Nanostructured Materials, and make the proposed Unit unique in the scientific and technological map of Cyprus are:
Computational and Simulations Materials Science: research within this activity will focus on modeling and design of advanced innovative materials for applied science and engineering applications, using a multiscale methodological approach spanning the entire spectrum from the atomistic to the macroscopic level.
Synthesis of Nanoengineered Materials: research will focus on the development and growth of nanostructured thin films with significant engineering applications including hard coatings, solid lubricants, wear-resistant layers for environmental protection, new coatings for solar energy applications, biocompatible coatings for medical applications.
Nanoscale Chracterization: research will concentrate on the determination, testing, characterization and nanoscale control of materials properties. Examples of techniques to be employed include nanoindentation, atomic force and scanning electron microscopy, X-ray diffraction, etc.
It should be noted that the synergistic approach between the three mentioned research directions is only found in a handful of materials research centers worldwide.
Computational and Simulations Materials Science: research within this activity will focus on modeling and design of advanced innovative materials for applied science and engineering applications, using a multiscale methodological approach spanning the entire spectrum from the atomistic to the macroscopic level.
Synthesis of Nanoengineered Materials: research will focus on the development and growth of nanostructured thin films with significant engineering applications including hard coatings, solid lubricants, wear-resistant layers for environmental protection, new coatings for solar energy applications, biocompatible coatings for medical applications.
Nanoscale Chracterization: research will concentrate on the determination, testing, characterization and nanoscale control of materials properties. Examples of techniques to be employed include nanoindentation, atomic force and scanning electron microscopy, X-ray diffraction, etc.