 |
| Automatic crystal detection program |
| Recording molecular movies |
 |
| Improving the durability of stainless steel |
| Visualizing the internal structures of nano-sized metal particles |
 |
| Super-tough materials for ceramics |
| Improving the mechanical reliability of ceramics |
| Fabrication of a new type of functional glass |
 |
| Mechanisms of innovative superconductors |
| Data storage for a massively growing data |
| ・超伝導になる電子をとらえる |
| ・電流も磁石も使わない磁気スイッチングへ |
| Magnetic field control without electric current |
| Achieving the long-held dream of "superconductivity at room temperature" |
| Unraveling the complex phenomena in many-body systems |
 |
| ・シリコン結晶の表面に酸素原子が反応する様子 |
| Atomic level examinations of electronics materials P25-2 LEDs with higher efficiency |
| LED's with higher efficiency |
| Fundamental research of extreme ultraviolet lithography (EUVL) |
| Improvement of fluorite lens performance |
| Materials mapping with element selectivity |
| Materials that have zero thermal-expansion ability |
| X-rays with a resolution close to the theoretical limit |
 |
| Mechanism for light-induced insulator-to-metal transition |
| New nano-particle science |
 |
| Hair care for healthy hair |
| Recovery of hair root collapse due to aging |
| Exploring the origin and spread of iron weapons |
 |
| Developing fuel-efficient engines for eco-friendly vehicles |
| Using hydrogen to reduce global warming |
 |
| Storage hydrogen like noble metals |
| ・貴金属元素に代わる普遍元素を用いて高活性・高選択的新型触媒へ |
| Development of catalysts |
| Examining the interiors of large batteries |
| A key to investigate the interfaces in fuel cells |
| Suppressing the diminishing of fuel cell performance |
| Synthesis of innovative hydrides |
| Mechanism-based process designing by manufacturing science |
