The International Symposium on Advanced Energy Materials and Next-Generation Storage Technologies (AEMST 2025) is the premier forum for the presentation of new advances and research results in the fields of advanced energy materials and next-Generation storage technologies.

Our wish is to give to all academics, industrials and government agents interested in advanced energy materials and next-Generation storage technologies the opportunity to present their work, studies or experiences.

Submitted paper will be peer reviewed by conference committees, and accepted papers will be included into Conference Proceedings which will be published and submitted to online database. Those papers will be submitted for indexing to EI-Compendex and Scopus.
We would also like to invite colleagues new to these fields to participate in this conference. 

Topics of interest for submission include, but are not limited to:

T1. Next-Generation Materials for Energy Conversion and Storage
• High-efficiency photovoltaic materials (perovskites, organic solar cells)
• Advanced electrocatalysts for fuel cells and water splitting
• Innovations in battery technologies (solid-state, Li-S, Na-ion)
• Supercapacitors and hybrid storage systems
• Hydrogen storage materials and sustainable production methods
• Bio-derived and biodegradable energy materials

T2. Supercapacitors and Hybrid Energy Storage Systems
• Carbon-based electrode design (e.g., graphene, carbon nanotubes)
• Pseudocapacitive materials and redox-active electrolytes
• Hybrid batteries-supercapacitor architectures for rapid charging
• Novel device configurations for enhanced energy and power density
• Advanced manufacturing methods for scalable production
• Integration of supercapacitors in consumer electronics and EVs
• Performance monitoring, safety considerations, and lifecycle analysis

T3. Advanced Battery Chemistries
• Lithium-ion, sodium-ion, magnesium-ion, and beyond
• Solid-state and semi-solid electrolytes for enhanced safety
• Novel anode and cathode materials for higher energy density
• Flow batteries and redox chemistries for large-scale applications
• High-voltage systems and advanced electrolyte additives
• Battery degradation mechanisms and lifespan extension strategies
• Cost-reduction techniques, manufacturing scalability, and commercial feasibility

T4. Materials Design and Characterization
• Computational modeling and AI-driven approaches to materials discovery
• High-throughput screening of novel compounds and composites
• In situ and operando characterization for real-time performance insights
• Multi-scale modeling: linking atomistic details to device-level properties
• Advanced coatings, surface modifications, and nanofabrication techniques
• Novel experimental methods for probing mechanical, thermal, and electrochemical properties
• Correlating structure-property relationships for targeted material optimization

T5. Lifecycle Analysis and Sustainability
• Environmental impact assessments and carbon footprint reduction
• Strategies for recycling and reusing energy storage materials
• Circular economy approaches in battery and fuel cell design
• Eco-friendly manufacturing processes and green chemistry solutions
• Policies, regulations, and incentives for sustainable energy systems
• Modeling and predicting end-of-life scenarios for storage technologies
• Global collaborations and case studies on sustainable development goals

T6. System Integration and Industrial Applications
• Grid-scale storage: balancing renewables and demand management
• Power electronics and battery management systems
• EV technologies and infrastructure: charging, swapping, and range extension
• Aerospace applications: high power-to-weight ratio systems
• Industrial IoT and smart manufacturing of energy devices
• Case studies of successful pilot projects and commercial deployments
• Future trends in digitalization, automation, and cloud-enabled energy solutions