Call for Abstract

Scientific Program

17th International Conference on Emerging Materials and Nanotechnology, will be organized around the theme “Unearthing the Researches in Materials Science and Nanotechnology”

Emerging Materials Congress 2019 is comprised of 12 tracks and 301 sessions designed to offer comprehensive sessions that address current issues in Emerging Materials Congress 2019.

Submit your abstract to any of the mentioned tracks. All related abstracts are accepted.

Register now for the conference by choosing an appropriate package suitable to you.

Track 1: Material Science and Engineering

  • Track 1-1Developments in Polymer Characterisation
  • Track 1-2Nuclear Engineering
  • Track 1-3Waste Development and Characterisation
  • Track 1-4Advanced Nuclear Materials Cements@Sheffield
  • Track 1-53D-Printed Materials and Systems
  • Track 1-6Thermal Spray Technology
  • Track 1-7Materials for Energy Infrastructure
  • Track 1-8Information Materials
  • Track 1-9Ferrous & Non ferrous Materials
  • Track 1-10Sustainable Construction Materials
  • Track 1-11 Materials Syntheses
  • Track 1-12MATERIALS SYNTHESIS AND PROCESSING
  • Track 1-13Shape-memory alloys for biomedical implants
  • Track 1-14Multicomponent alloys for light-weight vehicles or high-temperature engines
  • Track 1-15Intermetallic alloys for hydrogen storage
  • Track 1-16Advanced characterization by electron microscopy or atom probe of alloys with nanoscale precipitates
  • Track 1-17Smart materials and structures
  • Track 1-18Smart materials applications
  • Track 1-19Advanced Structural Materials
  • Track 1-20Biosensing and bioimaging
  • Track 1-21Physics and Chemistry of Materials
  • Track 1-22Materials for Green Technology
  • Track 1-23Materials for Green Technology
  • Track 1-24hybridizing metallurgy
  • Track 1-25solid-state physics
  • Track 1-26materials efficiency
  • Track 1-27advanced manufacturing
  • Track 1-28Metals and alloys
  • Track 1-29renewable and sustainable energy
  • Track 1-30Composite materials
  • Track 1-31Graphene and fullerenes
  • Track 1-32Quasi crystals
  • Track 1-33Thin films and coatings
  • Track 1-34Conductive materials
  • Track 1-35Semiconductor alloy system
  • Track 1-36Metals, Mining, Metallurgy and Materials

Track 2:Materials and Devices

  • Track 2-1Smart grid & Semiconductor Materials
  • Track 2-2Materials for Advanced Batteries
  • Track 2-3Liquid Crystal
  • Track 2-4Advanced Magnetic Materials & Devices
  • Track 2-5Functional Materials and Devices
  • Track 2-6Hybrid Automobiles
  • Track 2-7 Fuel cells
  • Track 2-8Capacitors (Super, Ultra, Pulsed Power)
  • Track 2-9Thermal storage materials
  • Track 2-10Intelligent sensors
  • Track 2-11Emerging energy harvesting technologies
  • Track 2-12Smart materials
  • Track 2-13Building materials
  • Track 2-14Photonics materials
  • Track 2-15Sensors and actuators
  • Track 2-16Optical fibers and laser technologies
  • Track 2-17Battery Powered Vehicles

Track 3:Nanotechnology in Materials Science

  • Track 3-1Micro/Nano Cell and Molecular Sensors
  • Track 3-2Nano-size Polymers
  • Track 3-3Nano and Biotech Based Materials
  • Track 3-4Micro and Nano Fabrication Technology
  • Track 3-5Quantum Nano-Photonics
  • Track 3-6Nano Convergence
  • Track 3-7Smart Materials-Based Actuators at the Micro/Nano-Scale
  • Track 3-8Nano, Quantum and Molecular Computing
  • Track 3-9Rubber Nano Blends
  • Track 3-10Redox Systems Under Nano-Space Control
  • Track 3-11Nano-Optoelectronics
  • Track 3-12Fracture of Nano and Engineering Materials and Structures
  • Track 3-13Molecular- and Nano-Tubes
  • Track 3-14Emissive Materials - Nanomaterials
  • Track 3-15Nanophysics
  • Track 3-16Nanomaterial Applications using Carbon Nanotubes
  • Track 3-17Nanomaterial Applications using Graphene
  • Track 3-18Nanomaterial Applications using Nanocomposites
  • Track 3-19Nanomaterial Applications using Nanofibers
  • Track 3-20Nanomaterial Applications using Nanoparticles
  • Track 3-21Nanomaterial Applications using Nanowires
  • Track 3-22Metallic Micro and Nano Materials
  • Track 3-23Micro and Nano Machining of Engineering Materials
  • Track 3-24Glassy, Amorphous and Nano-Crystalline Materials
  • Track 3-25Nanomaterials and Nanosystems for Biomedical Applications
  • Track 3-26Colloids for Nano- and Biotechnology
  • Track 3-27Nanomaterials and Nanoengineering
  • Track 3-28Nano Devices and Interfaces
  • Track 3-29Nano Manipulation
  • Track 3-30Nanomaterials
  • Track 3-31Nanocomposites
  • Track 3-32Nanoparticles
  • Track 3-33Computational Nanoscience
  • Track 3-34Nanophotonics
  • Track 3-35Nanomedicine
  • Track 3-36Quantum dots
  • Track 3-37Nanofabrication
  • Track 3-38Nanobiomaterials
  • Track 3-39Nanodrug delivery
  • Track 3-40Biomolecular Integrated Circuits
  • Track 3-41Photonics Innovation

Track 4:Catalysis and Energy Materials

  • Track 4-1Solar Energy Materials
  • Track 4-2Hydrogen Energy
  • Track 4-3Materials for Advanced Energy Systems
  • Track 4-4Materials for Chemical Sensing
  • Track 4-5Materials, Energy and Environment Engineering
  • Track 4-6Recent Advancements in Materials and Systems for Thermal Energy Storage
  • Track 4-7Energy from Organic Materials
  • Track 4-8Nanostructured Materials for Next-Generation Energy Storage and Conversion
  • Track 4-9Neutron Applications in Materials for Energy
  • Track 4-10High Energy Density Materials
  • Track 4-11Thermal Energy Storage Using Phase Change Materials
  • Track 4-12Modern Piezoelectric Energy-Harvesting Materials
  • Track 4-13Eco- and Renewable Energy Materials
  • Track 4-14Lithium ion batteries
  • Track 4-15Fuel cell materials
  • Track 4-16Solar energy materials
  • Track 4-17Thermoelectric materials
  • Track 4-18Photovoltaic devices
  • Track 4-19Semiconductor materials
  • Track 4-20Cryogenic materials
  • Track 4-21Piezoelectric nanogenerators as fuel cells
  • Track 4-223D batteries for micro-electronics
  • Track 4-23Organic batteries and photovoltaics
  • Track 4-24Supercapacitors and batteries

Track 5:Surface Science and Engineering

  • Track 5-1Theoretical Surface Science
  • Track 5-2Custom Materials Synthesis
  • Track 5-3 Superhydrophobic Surface Treatments
  • Track 5-4Hard, Scratch Resistant Barrier Coatings
  • Track 5-5Additive Manufacturing of Emerging Materials
  • Track 5-6Biofilm and Materials Science
  • Track 5-7Current Trends of Surface Science and Catalysis
  • Track 5-8Experimental Innovations in Surface Science
  • Track 5-9Surface Analysis Methods in Materials Science
  • Track 5-10Protection of Metals and Physical Chemistry of Surfaces
  • Track 5-11Coatings Technologies
  • Track 5-12Applied Adhesion Science
  • Track 5-13Surface Engineering and Tribology
  • Track 5-14Fundamentals of surface engineering
  • Track 5-15Surface coating and modification
  • Track 5-16Catalysis and electrochemistry
  • Track 5-17Nanoscale surface modifications
  • Track 5-18Corrosion and heat treatment

Track 6:Biomaterials and Tissue Engineering

 

 

  • Track 6-1Tissue engineering and regenerative medicine
  • Track 6-2Nano/Micro-Structured Materials for Energy and Biomedical Applications
  • Track 6-3Silicon Nano-biotechnology
  • Track 6-4Methodology Development
  • Track 6-5Biomaterials and Biominerals
  • Track 6-6Multiscale Materials Modelling
  • Track 6-7 Biosensing and bioimaging
  • Track 6-8 Drug and DNA targeting delivery
  • Track 6-9Biosensing and bioimaging
  • Track 6-10Biological interactions with nanomaterials
  • Track 6-11high-performance purification and stem-cell proliferation systems
  • Track 6-12subtle micromanipulation of extracellular cues
  • Track 6-13non-intrusive monitoring and analysis of functional biological substitutes
  • Track 6-14functional scaffolds to provide extracellular microenvironment
  • Track 6-15bioprocess synthesis, optimization and simulation
  • Track 6-16cheap & scalable bioprocesses
  • Track 6-17design and construct novel “programmable” cells
  • Track 6-18 novel bioproducts & bioreactors
  • Track 6-19Biotechnology and Molecular Bioscience
  • Track 6-20Resorbable biomaterials
  • Track 6-21Biochemical System and Processes
  • Track 6-22Biomimetic materials
  • Track 6-23Surface properties of biomaterials
  • Track 6-24Surface properties of biomaterials
  • Track 6-25Bio-inorganic nanomaterials
  • Track 6-26Computational studies of biomaterials
  • Track 6-27Soft materials
  • Track 6-28Biophysics

Track 7:Ceramic Engineering

  • Track 7-1Mechanical Properties of Glass
  • Track 7-2Nanolithography
  • Track 7-3Oxide multiferroics
  • Track 7-4Oxide ferroelectrics
  • Track 7-5Solid oxide fuel cell materials
  • Track 7-6Cellular ceramics
  • Track 7-7Gel casting
  • Track 7-8Thermal and environmental barrier coatings-Ceramic
  • Track 7-9Advanced Ceramic Coating
  • Track 7-10Advanced Bio- and Medical Ceramics
  • Track 7-11Advanced Electroceramics
  • Track 7-12Advanced Optical Ceramics
  • Track 7-13Advanced Non-Oxide Ceramics
  • Track 7-14Advanced Carbons
  • Track 7-15Self-Healing Fiber-Composites
  • Track 7-16Hybrid and Hierarchical Composite Materials
  • Track 7-17Functional Ceramics
  • Track 7-18Stronger Materials/Higher Strength Composites
  • Track 7-19Ceramic Metal Oxides
  • Track 7-20Bio inert Materials
  • Track 7-21Bio Ceramics
  • Track 7-22Composite Ceramics
  • Track 7-23Solid Oxide Fuel Cells
  • Track 7-24Ceramic materials for solid oxide fuel cells
  • Track 7-25Ultra high temperature composites
  • Track 7-26Bioceramics
  • Track 7-27Applications of Porous Ceramics
  • Track 7-28Ceramics for body and vehicular armour
  • Track 7-29Glass-ceramic
  • Track 7-30Advanced Ceramics
  • Track 7-31Biocomposites

Track 8:Polymers

  • Track 8-1Polymers and Composites
  • Track 8-2Conducting polymers
  • Track 8-3Self-assembled block-copolymers
  • Track 8-4Antifouling polymers
  • Track 8-5Biocompatible polymers for tissue engineering
  • Track 8-6Polymer electronics and photonics
  • Track 8-7Nanomaterial-polymer composite materials with superior mechanical properties
  • Track 8-8Polymer Coatings for Fabrics
  • Track 8-9Self-Healing Polymers
  • Track 8-10Conductive polymers
  • Track 8-11Fracture of Non-Metallic Materials
  • Track 8-12Polymeric Dental Materials
  • Track 8-13Lignocellulosic Composite Materials
  • Track 8-14 Natural polymer modifications
  • Track 8-15Polymer scaffolds used for various biotechnological applications
  • Track 8-16 Polymer nanocomposites
  • Track 8-17Biopolymers
  • Track 8-18Nanocomposite Polymer Electrolytes
  • Track 8-19Functional Polymers and Polymer Hybrid Materials
  • Track 8-20Organic polymer chemistry
  • Track 8-21Composite polymers and plastics
  • Track 8-22Polymer engineering
  • Track 8-23Inorganic -organic hybrid systems
  • Track 8-24Polymers for biomedical applications
  • Track 8-25Polymers for textile and packaging
  • Track 8-26Advanced polymer applications

Track 9:Advanced Graphene and Carbon Materials

Graphene is the crystalline form of carbon that has two dimensional (2D) properties where it consists of single layer of carbon atom arranged in hexagonal lattice. This allotrope of carbon is the basic structure of other allotropes such as diamond, carbon nanotubes, graphite, fullerenes. Graphite which is one of the allotrope of carbon is the softest material with is very good lubricant and is the conductor of electricity. Because of its known unique property, it is being used as thermal insulation. Natural graphite is of three types as crystalline, amorphous and vein. Carbon has numerous essential application in the living system. Carbon fibers which is composed mostly of carbon events, in the range of 5-10 micrometers has its application in composite materials, textiles, microelectrodes, Flexible heating. Carbon Nanotube is the cylindrical form of the allotropes of carbon has unusual thermal conductivity, mechanical and electrical properties and is valuable in the arenas of materials science, nanotechnology, electronic and optics.

 

  • Track 9-1Carbon dots
  • Track 9-22D Materials heterostructures and superstructures
  • Track 9-3Graphene analogs
  • Track 9-4Hydrogen Technologies
  • Track 9-5Solarthermal Energy
  • Track 9-6Chemical functionalisation of Graphene
  • Track 9-7Graphene based products
  • Track 9-8Applications of Carbon in Energy
  • Track 9-9Carbon nanotubes and graphene
  • Track 9-10Semiconductor Materials and Nanostructures

Track 10:Electrical, Optical, Magnetic Materials

 

 

  • Track 10-1 Lasers in Manufacturing and Materials Processing
  • Track 10-2Optical Properties of Advanced Materials
  • Track 10-3Applied Nano-Electromagnetics
  • Track 10-4Nonlinear Super-Resolution Nano-Optics and Applications
  • Track 10-5Nano-Electronic Devices
  • Track 10-6Nano-Optics and Nanophotonics
  • Track 10-7Progress in Nonlinear Nano-Optics
  • Track 10-8Biomedical Optical Instrumentation and Laser-Assisted Biotechnology
  • Track 10-9Atomic, Molecular, Optical & Plasma Physics
  • Track 10-10Imaging, microscopy, adaptive optics
  • Track 10-11Photonics
  • Track 10-12Laser beam delivery and diagnostics
  • Track 10-13Lasers in medicine and biology
  • Track 10-14Optical nanomaterials for photonics/biophotonics
  • Track 10-15Advanced spintronic materials
  • Track 10-16Dielectric materials and electronic devices
  • Track 10-17Engineering applications of spectroscopy

Track 11:Advanced Materials

 

 

  • Track 11-1 Advanced Aerospace Materials
  • Track 11-2Bio-aggregates Based Building Materials
  • Track 11-3Physics of New Materials
  • Track 11-4Cement Replacement Materials
  • Track 11-5Materials for Advanced Packaging
  • Track 11-6Degradation of Implant Materials
  • Track 11-7Materials with Complex Behaviour
  • Track 11-8Materials Management
  • Track 11-9Mechanics of Advanced Materials
  • Track 11-10Materials Selection and Design
  • Track 11-11Food Packaging Materials
  • Track 11-12Electroactive Materials
  • Track 11-13Materials for Nuclear Plants
  • Track 11-14From Molecules to Materials
  • Track 11-15Heterogeneous Materials
  • Track 11-16Issues in Materials Development
  • Track 11-17Frontiers of Nano-Optoelectronic Systems
  • Track 11-18Microwave Materials
  • Track 11-19Nanostructured Materials
  • Track 11-20Building materials
  • Track 11-21Claytronics
  • Track 11-22Aerogels
  • Track 11-23Graphene
  • Track 11-24Design of New Materials
  • Track 11-25Meta materials
  • Track 11-26Materials Beneficiation

Track 12:Materials Characterization and Applications

  • Track 12-1Materials with Internal Structure
  • Track 12-2Battery Testing
  • Track 12-3Dispersions Characterization
  • Track 12-4Coatings Characterization
  • Track 12-5Powder Characterization
  • Track 12-6Nondestructive Characterization of Materials
  • Track 12-7Practical Materials Characterization
  • Track 12-8Microscopy of Semiconducting Materials
  • Track 12-9Photorefractive Effects and Materials
  • Track 12-10Advanced Structural and Functional Materials
  • Track 12-11Materials Synthesis and Characterization
  • Track 12-12Atomistic Modeling of Materials Failure
  • Track 12-13Progress in Materials Analysis
  • Track 12-14Formability of Metallic Materials
  • Track 12-15Characterization of Advanced Materials
  • Track 12-16Materials Characterisation and Mechanism of Micro-Cutting
  • Track 12-17Nanoscale Imaging and Characterisation
  • Track 12-18Hydrogen Storage Materials
  • Track 12-19Nanoscale Characterisation of Ferroelectric Materials
  • Track 12-20Failure analysis
  • Track 12-21Material comparisons
  • Track 12-22De-formulation
  • Track 12-23Reverse engineering
  • Track 12-24Crystallographic Texture of Materials
  • Track 12-25Phase Change Materials
  • Track 12-263D printed organs
  • Track 12-27Ultrasonic Testing of Materials