|
Improvements in solar energy |
Determining how cells can transport nutrients across cell membranes |
Recording molecular movies |
Understanding the sources of dysfunction in molecular motors |
Understanding how we can sense taste |
|
Critical clues for discovering g new pharmaceutical drugs |
|
Whole cell visualization with negligible radiation damage |
New functional materials for artificial muscles |
Interior imaging of a living cell in a solution |
|
Hydrogen storage using aluminum-based materials |
Development of a tungsten recycling process |
Development of materials for building more resilient infrastructure |
Higher quality and performance for steel |
|
Observing the atomic and molecular dynamics at a rate of 1/10,000,000sec. |
New material made of tough polymers for the bodies of electric vehicles |
Improving the mechanical reliability of ceramics |
Controlling durability and flexibility at the molecular level |
Toward effective use of light element materials |
Development of tires with greater fuel efficiency |
|
More eco-friendly cars and higher efficiency wind-power generators |
High-performance memory using spintronics materials |
Development of spintronics solid-state devices |
Development guidelines for advanced magnetic devices |
Power-saving telecommunications technology using magnetization |
Magnetic memory devices with ultra low-power consumption |
Innovative Superconducting State |
・超伝導になる電子をとらえる |
Unveiling the mechanisms of high-temperature superconductors |
Domain wall driven by a magneto-electric effect |
Controlling magnetic memory with electric fields |
Development of new electronic devices |
Magnetic field control without electric current |
Unraveling the complex phenomena in many-body systems |
Achieving the long-held dream of "superconductivity at room temperature" |
・隕石に由来する高機能磁性材料の人工作製 |
|
・シリコン結晶の表面に酸素原子が反応する様子 |
LED's with higher efficiency |
Higher efficiency power generated material by vibration |
Higher-performance LED devices |
New peep prevention filter |
Highly-durable luminescent materials |
Investigation of physical properties using photoelectrons |
X-rays with a resolution close to the theoretical limit |
|
More brilliant XFEL |
Ultimate focusing of an X-ray laser beam |
Maintenance-free materials |
Devices for next-generation optical computing |
Visualizing materials that are invisible to electron microscopes |
|
Eco-friendly diatoms |
Thin film storing gas |
Developing fuel-efficient engines for eco-friendly vehicles |
・希少元素のリサイクルへ |
Exhaust gas purification that does not require precious metals |
New cooling technology using solid refrigerants |
Damage-free analysis of catalysts |
Using hydrogen to reduce global warming |
Understanding how hydrogen is stored in materials |
Developing a "mineral" for the safe disposal of geological materials |
|
Lithium-ion battery development using machine learning and mathematics |
Effective use of hydrogen as a clean energy source |
Nanosheets: innovative solar cell materials |
More durable lithium-ion batteries |
Making batteries that are all-solid-state |
Storage hydrogen like noble metals |
Using a huge current over a short period |
・固体酸化物燃料電池(SOFC)の熱耐久性の改善へ |
Revealing the secrets of photosynthesis |
Electron motion in photocatalysts |
High-performance lithium-ion batteries (LIBs) |
Next-generation fuel cell electrode catalysts |
Improving the performance of storage batteries |
More efficient power generation |
Development of catalysts |
Basis for plant gene modification and artificial photosynthesis |
Information for the design of artificial enzymes |
Moving toward a "hydrogen society" |
Dramatic improvements in solar utilization efficiency |
High-performance storage batteries |
Understanding the mechanisms of batteries |
New techniques for diagnosing batteries |
・塗って作れる太陽電池で変換効率10%を達成 |
In situ observation of the operating state of batteries |
Visualizing the interior of an operating battery |
Electrochemical phenomena in fuel cells under operating conditions |
Producing organic compounds from CO2 and H20 using sunlight energy |
A key to investigate the interfaces in fuel cells |
Long-life and high-quality fuel cells for the future |
Suppressing the diminishing of fuel cell performance |
Clarifying catalytic reaction mechanisms of polymer electrolyte fuel cells |
Ultrafast oscillation of molecules |
High durability fuel cell electrodes |
|
Understanding and designing functional materials |
・レーザー溶接中の内部の様子 |
Improving the eco-friendliness of electric vehicles |
Synthesis of innovative hydrides |
Mechanism-based process designing by manufacturing science |
|
Developing high-performance furnaces that are X-ray-transparent |
Exploration the potential of space resource mining in the near future |
Possible e presence of noble iron hydride in Earth's interior |