ABSTRACT INFORMATION & SUBMISSION
We are inviting the submission of scientific abstract for presentations at the conference.
Our conferences has drawn top researchers from around the world to share their insights. The conference aims to serve as a dynamic platform for scientists and researchers worldwide to engage in the exchange of cutting-edge scientific information, fostering meaningful connections, and potentially forging collaborative partnerships. With a dedicated focus on the conference topics, we aspire to facilitate the advancement of knowledge and innovation in our collective pursuit of scientific excellence.
Authors are invited to submit their abstracts under one of the following topics:
| Advanced materials for energy storage: Batteries, supercapacitors, and fuel cells |
| Advanced materials for energy-efficient electronics and power devices |
Advanced materials for energy-efficient sensors and energy harvesting systems |
Advanced materials for hydrogen production, storage, and utilization |
Emerging energy storage technologies: Solid-state batteries, flow batteries, etc. |
Energy conversion and storage in nanomaterials and nanostructures |
Energy harvesting materials and devices: Thermoelectrics, piezoelectrics, and triboelectric materials |
Energy materials for water splitting and artificial photosynthesis |
| Energy materials: Synthesis and characterization |
Energy-efficient building materials and technologies |
Energy-related materials modeling, simulation, and characterization techniques |
Environmental impact and life-cycle analysis of energy materials and technologies |
Materials and technologies for energy storage in electric vehicles |
Materials and technologies for lithium-ion batteries: Advancements and challenges |
Materials characterization techniques for energy materials and technology |
Materials for advanced energy conversion technologies: Solar thermal, concentrated solar power, and thermophotovoltaics |
Materials for carbon capture, utilization, and storage (CCUS) |
Materials for energy storage in grid-scale applications: Flow batteries, compressed air energy storage (CAES), and pumped hydroelectric storage |
| Materials for energy-efficient and lightweight transportation: Electric vehicles, hybrid vehicles, and aerospace applications |
| Materials for energy-efficient catalysis and chemical processes |
| Materials for energy-efficient electronics and power devices |
| Materials for energy-efficient insulation and thermal management |
| Materials for energy-efficient lighting: LEDs, phosphors, and organic light-emitting diodes (OLEDs) |
| Materials for hydrogen storage and fuel cells |
| Materials for photovoltaics: Solar cells, thin films, and perovskite materials |
| Materials for sustainable and renewable energy applications |
| Nanomaterials and nanostructures for energy applications: Synthesis, characterization, and performance optimization |
| Nanomaterials for energy conversion and storage applications |
| Nanogenerator and piezoelectronics |
| Novel materials and designs for energy-efficient buildings and infrastructure |
| Organic photovoltaic materials and devices |
| Perovskite solar cells: Materials development and stability enhancement |
| Smart windows and transparent solar cells: Novel materials and applications |
| Solar energy materials and photovoltaic technologies |
| Sustainable materials for energy production: Biomass, biofuels, and waste-to-energy |
| Thin-film solar cells: Materials, manufacturing, and efficiency improvements |
| Characterization and metrology of nanomaterials |
| Commercialization and industrial applications of nanomaterials |
| Gold nanoparticles |
| Nano-biosensors |
| Nanocomposites and hybrid nanomaterials |
| Nanodevices and nanosensors |
| Nanoelectronics and nanophotonics |
| Nanomaterials and nanotechnology – Physics, chemistry and biology |
| Nanomaterials for 3D printing and additive manufacturing |
| Nanomaterials for advanced coatings and surface engineering |
| Nanomaterials for agriculture and food industry |
| Nanomaterials for biomedical applications |
| Nanomaterials for biotechnology and bioengineering |
| Nanomaterials for catalysis and chemical processes |
| Nanomaterials for drug delivery and therapeutics |
| Nanomaterials for electronics and optoelectronics |
| Nanomaterials for energy applications |
| Nanomaterials for energy storage and conversion |
| Nanomaterials for environmental applications |
| Nanomaterials for flexible and wearable electronics |
| Nanomaterials for photonics and plasmonics |
| Nanomaterials for tissue engineering and regenerative medicine |
| Nanomaterials for water purification and desalination |
| Nanomaterials synthesis and fabrication techniques |
| Nanoscale devices and sensors |
| Nanoscale fabrication and manufacturing techniques |
| Nanotechnology and quantum computing |
| Nanotechnology for space exploration and aerospace applications |
| Nanotechnology for sustainable development |
| Nanotechnology for water and air filtration |
| Nanotechnology in agriculture and food industry |
| Nanotechnology in medicine and healthcare |
| Nanotechnology in optics and photonics |
| Nanotoxicology and safety aspects of nanomaterials |
| Physico-chemical nanomaterials and nanotechnology |
| Synthesis and characterization of nanomaterials |
| 2D materials and their functional applications |
| Advanced characterization techniques for functional materials |
| Advanced functional polymers and composites |
| Biomimetic and bioinspired materials: Design and functional properties |
| Commercialization and industrial applications of functional materials |
| Computational modeling and simulation of functional materials |
| Emerging technologies and applications of functional materials |
| Ferroelectric and piezoelectric materials |
| Functional coatings and surface engineering |
| Functional materials for biomedical applications |
| Functional materials for catalysis and chemical processes |
| Functional materials for electronics and optoelectronics |
| Functional materials for energy conversion and storage |
| Functional materials for environmental monitoring and remediation |
| Functional materials for medical and healthcare applications |
| Functional materials for sensors and actuators |
| Functional materials for wearable technology and flexible electronics |
| Functional nanomaterials: Synthesis, characterization, and applications |
| Functional carbon/ quantum dots |
| Functional materials based technology, innovations and market |
| Functional polymeric materials |
| Magnetic and spintronic materials: Properties and applications |
| Materials for energy conversion and storage |
| Multifunctional composite materials: Design, fabrication, and properties |
| Multifunctional materials: Design, synthesis, and characterization |
| Photonic and plasmonic materials: Design, fabrication, and applications |
| Piezoelectric and ferroelectric materials: Design and device integration |
| Self-healing materials and technologies |
| Shape memory materials: Behavior, applications, and advancements |
| Smart materials and structures: Responsive and adaptive behavior |
| Soft and flexible functional materials |
| Stimuli-responsive and adaptive materials |
| Superconducting materials and applications |
| Additive manufacturing of composite and ceramic materials |
| Advanced composite materials: Design, fabrication, and characterization |
| Bio-inspired composites: Structure, mechanics, and applications |
| Biomaterials and bioceramics: Design, fabrication, and biomedical applications |
| Ceramic coatings and surface engineering: Deposition techniques, properties, and applications |
| Ceramic materials for electronic and photonic applications |
| Ceramic materials for energy applications: Fuel cells, solar cells, and batteries |
| Ceramic matrix composites: Processing, properties, and applications |
| Ceramic nanomaterials: Synthesis, assembly, and functionalization |
| Characterization techniques for composite and ceramic materials |
| Composite and ceramic materials for aerospace and automotive applications |
| Composite and ceramic materials in medical and dental applications |
| Electrically and thermally conductive composites |
| Environmental and sustainability aspects of composites and ceramics |
| Fiber-reinforced composites: Manufacturing and performance |
| High-temperature ceramics and composites |
| Hybrid composites: Combining different material types for enhanced performance |
| Industrial applications and commercialization of composite and ceramic materials. |
| Lightweight and high-strength materials |
| Modeling and simulation of composite and ceramic materials |
| Multifunctional composite materials |
| Nanocomposites and nanoceramics |
| Polymer-ceramic composites |
| Polymer-matrix composites: Manufacturing, performance, and optimization |
| Processing innovations in composites and ceramics |
| Smart and multifunctional composites: Sensing, actuation, and self-healing capabilities |
| Smart and responsive composite materials |
| Structural ceramics: Processing, characterization, and mechanical properties |
| Structural health monitoring of composite materials |
| Sustainable and eco-friendly composites: Recycling, biodegradability, and life-cycle assessment |
| Antibacterial and antimicrobial biomaterials |
| Bioactive and antimicrobial materials for infection control |
| Bioactive coatings and surface modifications for medical devices |
| Bioactive glasses and ceramics for medical applications |
| Bioactive materials for wound healing and tissue repair |
| Biocompatibility assessment and testing of biomaterials and biodevices |
| Biocompatible and bioresorbable materials: Design and applications |
| Biocompatible polymers and hydrogels for biomedical applications |
| Biodegradable and bioresorbable materials for medical applications |
| Biodegradable stents and cardiovascular devices |
| Biodevices for drug screening and personalized medicine |
| Bioelectronics and implantable medical devices |
| Biofabrication and 3D bioprinting of tissues and organs |
| Bioinspired and biointerfacing materials for improved biocompatibility |
| Biomaterial-host interactions and biocompatibility assessment |
| Biomaterials and biodevices in nanomedicine and nanotechnology |
| Biomaterials for cardiovascular, dental and orthopedic applications |
| Biomaterials for drug delivery and controlled release systems |
| Biomaterials for neural interfaces and neuroengineering |
| Biomaterials for tissue engineering and regenerative medicine |
| Biomaterials: Synthesis and characterization |
| Biomechanics and mechanobiology of biomaterials |
| Biomedical applications of 3D printing and additive manufacturing |
| Biomimetic materials and structures for biomedical engineering |
| Biosensors and diagnostic devices for healthcare monitoring |
| Imaging and visualization devices |
| Implantable biodevices and bioelectronics |
| Lab-on-a-chip and microfluidic devices |
| Nanomaterials and nanoparticles for targeted drug delivery |
| Radio and photo therapy devices |
| Wearable biodevices and biosensors |
| Electronic, magnetic and optical materials: Products, challenges and market |
| Electronic, magnetic and optical materials: Structure and design |
| Electronic, magnetic and optical materials: Synthesis and characterization |
| Electronic, magnetic and optical materials: Various applications |
| Hybrid electronic, magnetic and optical materials |
| Luminescence mechanisms and energy transfers |
| Magnetism, electromagnetism and spintronics |
| Magnetostrictive materials and device technologies |
| Nanoscale electronic, magnetic and optical materials |
| Piezoelectric materials and device technologies |
| Chemical safety and sustainability |
| Chemicals management and green economy |
| Environmental and green nanotechnology |
| Green and sustainable chemistry education |
| Green catalysis |
| Green chemistry in environmental science |
| Green fossil energy, biomass, and future fuels |
| Green solvents |
| Green synthesis, manufacturing, and engineering processes |
| Green technologies |
| Innovation in sustainable and green chemistry |
| Recycling and waste management |
| Application of biosensors in drug delivery and clinical chemistry |
| Bioelectronics and bioinstrumentation |
| Biological materials |
| DNA Chips |
| Enzyme-based biosensors |
| Immunosensors |
| Lab-On-A-Chip |
| Nanoelectronics biosensors |
| Natural and synthetic receptors |
| Novel transducers and photonic sensor technologies |
| Organism- and whole cell-based biosensors |
| Sensors |
| μ-TAS |
| Carbon materials characterization techniques and modeling |
| Carbon materials for additive manufacturing (3D printing) |
| Carbon materials for biomedical applications |
| Carbon materials for catalysis and chemical processes |
| Carbon materials for hydrogen storage and fuel cells |
| Carbon materials for sustainable and green technologies |
| Carbon materials for thermal management and heat transfer applications |
| Carbon materials for water purification and desalination |
| Carbon materials in advanced manufacturing and aerospace applications |
| Carbon nanomaterials: Synthesis, properties, and applications |
| Carbon nanotubes: Growth, functionalization, and device applications |
| Carbon-based coatings and surface modifications |
| Carbon-based composites and hybrid materials |
| Carbon-based electrodes and supercapacitors |
| Carbon-based sensors and actuators |
| Fullerenes |
| Glassy carbon |
| Graphene and graphene-related materials |
| Graphite |
| Porous carbons |
| Pyrolytic carbon |
| Carbon blacks |
| Carbon materials for energy storage and conversion |
| Carbon materials for energy-efficient buildings and infrastructure |
| Carbon materials for environmental applications |
| Carbon materials for flexible electronics and wearable devices |
| Carbon fibers and filaments |
- Ab Initio Calculations
- Computational Materials Science
- Computer-Aided Learning and Teaching
- Computer-Aided Materials Selection, Design and Manufacturing
- Computer-Integrated Material Processing Technology
- Density Functional Theory
- Finite Element Analysis and Mesoscale modelling
- Internet of Things-Based Methods
- Monte Carlo and Molecular Dynamics Techniques
- Nanoscale Modelling
- Quantum Chemical, Semi-Empirical and Classical Approaches
| 2D Materials |
| Applications of Graphene |
| Bio-Graphene |
| Graphene Based Devices |
| Graphene Based Polymers |
| Graphene Nanoplatelets |
| Graphene Nanotubes |
| Graphene Sheets |
| Graphene Technology |
| Graphene: Modification and Functionalization |
| Graphene: Synthesis, Characterization |
| Mechanical Properties on Graphene |
| Inorganic Materials Synthesis |
| Lighting Materials and Technology |
| Macromolecular and Nanomaterial Synthesis |
| Materials Processing, Structure and Properties |
| Materials Synthesis |
| Metals and Alloys |
| Metamaterials |
| Solid state chemistry |
| Structural and Spectroscopic Probing |
| Synthetic materials chemistry |
| Thin-film Processing |
| Applications of Polymers |
| Dynamics of Block Copolymers |
| Dynamics of Polymer Melts and Glasses |
| Functional Polymeric Materials |
| Polymer Composites and Blends |
| Polymer Membranes |
| Polymer Structure Modification by Chemical and Physical Means |
| Polymer Synthesis and Characterization |
| Semiconductors |
| Stimuli-Responsive and Sensory Polymers |
| Thermoplastic and Functional Elastomers |
| Computational Structural Mechanics |
| Computer-Aided Design and Modelling |
| Concrete and Masonry Structures |
| Construction Technology and Methods |
| Glass and Ceramics |
| Innovative Solutions in Structural Design and Construction |
| Materials Processing and Manufacturing |
| Membrane Structures |
| Metal and Alloys |
| Numerical Methods and Algorithms |
| Shape Memory Alloys |
| Smart Materials and Structures |
| Structural Analysis and Design |
| Structural Failures |
| Structural Stability, Safety and Reliability |
| Biomolecules, Biointerfaces, and Applications |
| Corrosion Engineering |
| Deposition Techniques |
| Nanostructured Materials, Micelles, and Colloids |
| Solid Thin Films and Layers |
| Surface and Interface Analysis and Properties |
| Surface and Interface Phenomena |
| Surface Coating Technology |
| Thin Film Growth and Epitaxy |
| Tribology |
The scientific committee of the conference will review all submitted abstracts and will determine if an abstract is to be presented orally or poster along with the acceptance letter.
Important Note: Copies of overheads or PowerPoint slides are NOT ACCEPTABLE as your written abstract
It is intended to serve as in-person and online platform for the speakers to showcase their highly insightful research work, knowledge from the field of materials science, engineering and technology to the audience and participants.
Abstracts failing to meet minimum standards or are not relevant to this conference will be declined. Authors may submit multiple abstracts, but usually an individual will not be offered more than one oral presentation.
Selected abstracts will be listed in the conference proceedings & abstracts book of the confirmed registered participants. We kindly request that you keep in mind of the deadline for abstract submissions.