Call for Papers
The Organizing Committee of ICESM 2025 invites researchers, academicians, industry professionals, and students to submit original research papers and review articles for presentation at the conference.
Submissions must be complete and adhere to a maximum length of twelve pages in a single-column format. Please note that prolonged literature review papers are not eligible for submission. However, review articles that present expanded findings and provide thorough comparative analyses based on observations are welcome and may be considered for approval.
Manuscript templates are available for download in both .docx and .pdf formats from the downloads section of the conference website. Submissions should include novel research concepts, ideas for further development, detailed analyses, conclusions, and outcomes. Manuscripts must not be under review or published in any other magazines, journals, or conference proceedings.
Each manuscript must include the names and affiliations of all authors, as well as the name and email address of the corresponding author.
Submissions should be prepared in the required single-column format, and soft copies of the full-length manuscripts in both .doc and .pdf formats should be emailed to [insert email address].
Topics but not limited to
Environmental Sciences
• Air and Water Pollution Monitoring and Mitigation.
• Climate Change Adaptation and Resilience Strategies.
• Advances in Waste Management and Recycling Technologies.
• Biodiversity Conservation and Restoration.
• Remote Sensing and GIS Applications in Environmental Studies.
Sustainable Materials
• Development and Applications of Green and Biodegradable Materials.
• Nanomaterials for Sustainability and Energy Efficiency.
• Sustainable Construction Materials and Techniques.
• Materials for Renewable Energy Systems (e.g., Solar Cells, Wind Turbines).
• Life Cycle Assessment of Sustainable Materials.
Renewable Energy and Resource Management
• Innovations in Solar, Wind, and Geothermal Energy Technologies.
• Circular Economy Practices in Energy and Materials.
• AI and IoT in Resource Optimization and Management.
• Water-Energy Nexus for Sustainable Development.
• Carbon Capture, Utilization, and Storage (CCUS) Techniques.
Advanced Functional Materials
• Materials for Energy Harvesting (e.g., thermoelectrics, piezoelectrics).
• Smart Materials: Shape-memory alloys and magneto-rheological fluids.
• Bio-inspired Materials for Medical and Environmental Applications.
• Self-healing and Adaptive Materials for Structural Applications.
Composite Materials
• Hybrid Composites for Aerospace and Automotive Applications.
• High-Temperature Composites for Turbine and Spacecraft Components.
• Functionally Graded Materials for Thermal Barrier Coatings.
• Additive Manufacturing of Customized Composite Structures.
Nanomaterials and Nanotechnology
• Carbon Nanotubes and Graphene for Energy Storage and Electronics.
• Nanofluids for Enhanced Heat Transfer in Solar Applications.
• Quantum Dots for Optoelectronics and Photovoltaics.
• Metal-Organic Frameworks (MOFs) for Gas Storage and Catalysis.
Advanced Manufacturing Materials
• High Entropy Alloys for Extreme Environment Applications.
• Materials for 3D and 4D Printing Technologies.
• Refractory Materials for Nuclear and Defense Applications.
• Coatings and Thin Films for Corrosion and Wear Resistance.
Materials for Environmental Applications
• Catalysts for Carbon Capture and Conversion.
• Phase Change Materials for Thermal Energy Storage.
• Photocatalytic Materials for Air and Water Purification.
• Perovskite Materials for High-Efficiency Solar Cells.
Process Optimization in Manufacturing
• Multi-Objective Optimization for Machining Processes (e.g., EDM, FSW).
• Optimization of Parameters in Powder Mixed Electric Discharge Machining (PMEDM).
• Energy and Material Efficiency Optimization in Additive Manufacturing.
• Design Optimization for Sustainable Manufacturing Systems.
Machine Learning and AI for Optimization
• AI-Based Predictive Modelling in Material Selection.
• Deep Learning for Structural Health Monitoring.
• Reinforcement Learning in Manufacturing Process Control.
• Genetic Algorithms and Swarm Intelligence for Design Optimization.
Environmental and Resource Optimization
• Energy Optimization in Renewable Systems (e.g., Wind, Solar).
• Life Cycle Optimization of Products for Circular Economy.
• Waste-to-Material Conversion Process Optimization.
• Optimization of Water-Energy-Food Nexus Systems.
High temperature Application
• High-Temperature Materials for Extreme Environments
• Coatings for High-Temperature Applications
• Manufacturing and Processing of High-Temperature Materials
• High-Temperature Composites
• High-Temperature Corrosion and Oxidation
• Testing and Characterization of High-Temperature Materials