AEMST 2026 offers a prominent venue for showcasing cutting-edge advances and research findings in advanced energy materials and next-generation storage technologies.
We warmly welcome domestic and foreign universities, scientific research institutions experts, scholars, business people and other relevant personnel to join us for exchange.
CFP Flyer
| T1. Next-Generation Materials for Energy Conversion and Storage |
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| • 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 |