Nano-sized silicon reacts rapidly with most water solutions to form pure hydrogen. However, high costlow availability are major issue. Our group has developed novel nano-sized silicon mass-production process, greatly improves its feasibilitycost for hydrogen generation. The in-time hydrogen generation by nano-size silicon, fuel-cell systemlithium ion battery system are all well integrated into one portable power system, which can satisfy general personnel electricity demand for some special conditions, such as battle field, emergency caseremote regions.

This project with aim of promoting digital optics education is funded by Ministry of Education. In the entry-level class, students are guided in the hand-on experiments to bring up the ability to set up optical pathsto learn the basic optics principles. In the advance-level class, students are encouraged to work on a 3D holographic project using the fast-response LCOS-SLM developed in Digital Optics Teaching Laboratory of NYCU. Students are able to apply different computer-generated holography (CGH) algorithmsdesign optical path accordingly to obtain desired holographic images.

Develop a SiC single-chip power system platform across processes, devices,circuits to breakthrough the temperaturepower constraints of Si applications. The research includes low-voltage CMOS logic circuits, high-voltage driver circuits,vertical super-junction MOSFETs. All specifications exceed existing technology. The results can be applied to energy networks, rail transit, new energy vehicles, geological exploration, aerospace, defenseother fields.

In the prior art of high-efficiency anode materials for lithium-ion batteries, we designed a high-entropy compositionmanufactured it through a simplemass production method. This technology inherits the cocktail effect of high-entropy alloys by combining highly active elementsmetal elements. This material can be manufactured by a simple mass production method. It shows high energy density, high Coulomb efficiencyhigh cycle stability,becomes a promising anode material for lithium-ion batteries.

A novel 3D-stack LTPO-based display array technology with CBRAM-embedded in a pixel has been successfully developed for the high-resolutionpower-saving near-eye VR/AR displays. Besides, a high-voltage gain CMOS inverter comprised by LTPO architecture is demonstrated acting as a digital driving circuit for the realistic FPD applications.