Conference Topics
Synthesis and Processing of Transition Metal–Doped Materials
- Nanopowders
- Single crystals
- Transparent ceramics
- Thin films
- Glasses
Structural and Spectroscopic Characterization
- Optical spectroscopy
- Electronic structure
- Luminescence
- Time-resolved spectroscopy
- Magnetic properties
- EPR, XPS, SEM, TEM, Raman, etc.
Transition Metal Materials for Photonics and Lasers
- Laser crystals and ceramics
- Tunable laser materials
- Saturable absorbers
- Mid-IR and near-IR photonic materials
Light Conversion and Luminescent Materials
- Transition metal phosphors and luminescent converters
- Down-conversion and up-conversion materials
- Persistent luminescence and phosphorescence
- Luminescent nanomaterials
Transition Metal Materials for Catalysis
- Heterogeneous catalysts based on transition metal oxides, sulfides, and carbides
- Tunable catalytic materials for selective reactions and process optimization
- Electrocatalysts and photocatalysts for energy conversion and environmental applications
- Catalytic systems for CO₂ reduction, water splitting, and pollutant degradation
Transition Metal Materials for Electronics
- Transition metal oxides, nitrides, and dichalcogenides for electronic devices
- Tunable electronic materials for transistors, memristors, and sensors
- Conductive and semiconductive thin films for integrated circuits and flexible electronics
- Materials for energy storage and conversion in electronic systems (e.g., supercapacitors, batteries)
Transition Metal Materials in Theory
- First-principles (DFT) studies of electronic structure and bonding in transition metal systems
- Multiscale modeling linking atomic-scale properties with device-level performance
- Simulation of charge transport, defects, and interfaces in transition metal materials
- Data-driven approaches and machine learning for materials discovery and property prediction