3^rd International Conference and Expo on Ceramics and Composite Materials June 26-27, 2017 Madrid, Spain

The thermal stability, wear-resistance and resistance to corrosion of ceramic components make the application of ceramic the ideal choice for many industrial uses. This track covers Medical Technology, Automotive Industry, Environment Technology, Mechanical and Metal Industry, Chemical Process Engineering, Engineering Service Providers, Electronics, Sensors and Semi-Conductor Industry, Others (armour, optics, wear, protection and corrosion).

The session will cover all aspects, from basic research and material characterization, through physicochemical aspects of growth and deposition techniques, to the technological development of industrialized materials. This track covers Semiconductors, Ferro/piezo-electric, Optical Materials, and Scintillator.

The influence of electrical fields on various phenomena in ceramic science is an emerging area which deals with the ceramic materials at higher temperatures and also the sintering characteristics shown by materials. This track covers Flash Sintering Phenomena and Mechanisms, Field Assisted Sintering Phenomena.

This track aims at bringing together engineers, technologists and scientists in the area of ceramic, carbon, glass and glass-ceramic materials containing high volume fractions of porosity, with porosity ranging from nano- to milli-meters. This track covers Innovations in Processing Methods and Synthesis of Porous Ceramics, Modeling and Properties of Porous Ceramics, Applications of Porous Ceramics, Mechanical Properties of Porous Ceramics.

Metal oxides represent an assorted and appealing class of materials whereby the field of metal oxide nanostructured morphologies has become one of the most active research areas within the nano-science community. This track covers Highly porous ceramic and metal materials, Composites based on shape-memory alloys, Design and manufacturing technology for ceramic and cermet composites with structural and phase transformations, Transformation-hardening ceramic and metal composite materials, Wear resistance of transformation-hardening ceramic and metal composite materials, Bioceramic Materials, Porcelain, Ceramics Manufacturers and Market Analysis.

Production Root Technology symbolically refers to an integration of six production technology groups; casting, molding, forming, welding, heat treatment, and surface treatment. This track covers New Concept & Emerging Technology, Shaping & Thermal Process, and Coating Process for Low Friction and Energy Solution, Innovative Process Technologies with Enhanced Performances of Products.

The technologies aiming for clean energy generation with zero-emission will require advances in materials developments for electricity generation as well as efficient and reliable energy storage. This track covers Solid Electrolytes and Characterization, Energy Harvesting and Storage.

This track covers recent advances in coating sciences and technologies, processing, microstructure and property characterization, and life prediction. This track covers Advanced Thermal Barrier Coatings: Processing and Development, Multifunctional, Corrosion and Wear, Environmental Barrier Coatings, Thermal Barrier Coatings: Characterization and NDE Methods, Advanced Multifunctional Coatings.

A composite material is made by combining two or more materials – often ones that have very different properties. The two materials work together to give the composite unique properties. This track covers Imaging of micro-defects, Adhesive layer effects, toughening of novel composites, Ceramic, Metallic and polymer matrix composites, Organic/inorganic hybrids.

Long-term mechanical reliability is a key issue in their ultimate use for a specific application. Correlations between processing and service conditions/environment to failure of ceramics by fracture, fatigue or deformation are key aspects of materials applications. This track covers Mechanics, Characterization Techniques, and Equipment, Tribology and Wear, Environmental Effects, Reliability and Small Scale Testing, Mechanical Behavior of CMCs, Processing - Microstructure - Mechanical Properties Correlation.

The purpose of ceramics processing to an applied science is the natural result of an increasing ability to refine, develop, and characterize ceramic materials. This track covers Phase equilibria in ceramic systems, Mechanical behavior and failure mechanisms, Sintering and Microstructure Development, Sol-gel techniques and thin film deposition.

Range in biocompatibility from the ceramic oxides, which are inert in the body, to the other extreme of resorbable materials, which are eventually replaced by the materials which they were used to repairing, used in many types of medical procedures. This track covers Biological Evaluation of Bioceramic Materials, Applications, Case Studies, and Bioceramics for Cancer Therapy, Bioceramics for Dental Application, and Bioceramics in Tissue Engineering.

The synthesis, characterisation and theoretical understanding of functional ceramic and inorganic materials. This area includes electroceramics (including ferroelectric, multiferroic and antiferroelectrics), complex oxides, solid state materials chemistry, inorganic framework and porous materials. This area does not include materials for energy applications, photonic, magnetic, superconducting, polymeric or composite materials or materials processing, as these are all covered in related research areas.

Ultra-High Temperature Ceramics are a family of compounds that display a unique set of properties, including extremely high melting temperatures (>3000°C), high hardness and good chemical stability and strength at high temperatures. Structural materials for use in high-temperature oxidizing environments are presently limited mostly to SiC, Si₃N₄, oxide ceramics and composites of these materials. The maximum use temperatures of silicon-based ceramics is limited to ~1600°C due to the onset of active oxidation (lower temperatures in water vapour environments), whilst oxides have exhibited high creep rates at higher temperatures. The development of structural materials for use in oxidizing and rapid heating environments at temperatures above 1600°C is therefore of great engineering importance.