| Phase 1 |
Development of Nano-hybrid interface technology |
- Development of key element technology for a hybrid, composite structure with super-high strength and high durability
- Development of groundbreaking technology for hybrid adhesive materials with super-high strength and high thermal resistance
- Development of groundbreaking technology for high-efficient, organic/inorganic hybrid thermoelectric modules
- Development of interface technology for materials for composite electronics
- Development of groundbreaking technology for 3D integrated semiconductor materials to materialize elements with high performances, equivalent to mechanical brains
- Development of processing technology based on hybrid interfaces
- Development of rod-shaped hybrid materials, tailored to interface optimization
- Development of groundbreaking technology for highly active catalysts for the future of the chemistry industry
- Development of groundbreaking technology for highly active composite structures that are MOF based
|
Breaking technology |
| Phase 2 |
Development of micro-hybrid interface processing technology |
- Platform technology of high adhesion strength hybrid-materials
- Development of analytical methodology for multi-functional materials
- 3D integrated semiconductor material for high performance neuromorphic logic technology
- Technology for simultaneous increasing trade-off properties by interface control of second phase in copper alloy
- Self-assembly-assisted 3-dimensional nanotransfer-printing and its applications for nanomaterials and energy devices
- Development of Energy Harvesting Technology by Multiferroic Interfacial Coupling Effect
- Multiscale simulation for growth mechanism and mechanical property of Nb thin film
- Development of Principal Technologies Related with Hybrid Interface for New Applications
- A Study on Fundamental Technologies for Active Interface
- Development of catalytic technology for future chemical industry
- Development of hybrid interface binder for nanoporous materials as catalyst substrate
- Development of highly active MOF-based nanocomposite materials
- Development of well tailored rod-shaped hybrid materials with interface optimization
- Development of High efficiency energy materials and devices via molecular and atomic scale controls
- The original technology of highly efficient organic/inorganic hybrid TE module
- Materials Computation
|
Development of application technology |
| Phase 3 |
Development of hybrid interface applied components |
- Platform technology of high adhesion strength hybrid-materials
- Development of analytical methodology for multi-functional materials
- 3D integrated semiconductor material for high performance neuromorphic logic technology
- Technology for simultaneous increasing trade-off properties by interface control of second phase in copper alloy
- Self-assembly-assisted 3-dimensional nanotransfer-printing and its applications for nanomaterials and energy devices
- Development of Energy Harvesting Technology by Multiferroic Interfacial Coupling Effect
- Multiscale simulation for growth mechanism and mechanical property of Nb thin film
- Development of Principal Technologies Related with Hybrid Interface for New Applications
- A Study on Fundamental Technologies for Active Interface
- Development of catalytic technology for future chemical industry
- Development of hybrid interface binder for nanoporous materials as catalyst substrate
- Development of highly active MOF-based nanocomposite materials
- Development of well tailored rod-shaped hybrid materials with interface optimization
- Development of High efficiency energy materials and devices via molecular and atomic scale controls
- The original technology of highly efficient organic/inorganic hybrid TE module
- Materials Computation
|
Development of technology to be commercialized |
