A Metal-Supported Solid Oxide Fuel Cell (MS-SOFC) unit cell with high electricity power output, stability, thermal-shock, mechanical-shock resistanceanti-redox abilities was successfully produced by a continuous fabrication process. This product can be installed not only in stationary SOFC power system but also in transportation set-up. The core technology of the fabrication process is Atmospheric Plasma Spraying (APS) technique which was employed to produce desired functional oxide lays onto permeable Nickel-base super alloy substrate.

The developed innovativegreen electrolyzed catalysis (EC) system can generate high concentrations of hydroxyl radical (OH·)nanobubbles, which can remediate TPH-contaminated soilgroundwater effectivelyeconomically. The EC system applies high voltagehigh electric fielduses direct current to change the structure of water molecular. Under activities of high voltagecatalystselectrolysis reactions, the electric discharges can produce EC water containing ·OH for TPH oxidation without secondary pollution. Nanobubbles can produce ·OH continuously after bursting.

A composite multi-cation high-entropy catalyst, which integrates the concept of high-entropy compounds into traditional metal oxide catalysts, such as spinel, perovskite, and fluorite structure. By the combination of photoelectric, piezoelectric, and ferroelectric materials with the characteristic high-entropy oxides. The high-entropy composite piezoelectric catalysts could become a promising technology for clean energy applications, such as organic dye degradation and hydrogen generation.

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 invention provides a method for synthesis a catalyst for catalyzing hydrogenation of CO2 to methanol. The precipitation process was controlled at 70 oCaging for 1.5 hour. The CuO: ZnO: Al2O3 weight ratios are 7: 3: 1. The particle size of CuO is less than 5 nm. The reaction is carried at 50 bar250 oC, CO2/H2= 1/3. Adding hydrophobic fumed silica, water is expelled from catalyst surface,the reaction can shift to product side. Therefore the CO2 conversion can reach 90 thermodynamic equilibrium conversion, methanol selectivity is greater than 95.

Metal-organic framework is a kind of regular porous material which is self-assembled by metal ion centerorganic ligand framework. I used the metal-organic framework as a templateprecursor to successfully develop a low-cost bimetallic phosphide, which exhibits excellent water splitting hydrogen production performance. The on-site real-time change experiment technology provided by Taiwan Photon Source is a great weapon for real-time detection of active sitesreaction centers during the development of key catalyst materials.

Here we developed a fastgreen process of micro-plasma system for three-dimensional porous nanomaterials on low-cost paper substrates. The characteristics are low-cost, flexible,high-stability. It has three major applications, including increasing Raman measument, the detection process can be used with portable Raman spectroscopy for fast sensing,it can quickly analyze pesticides, food, drugs, etc. In addition, it can be equipped with boron nitride for high hydrogen productionhigh pollution biodegradationother applications.

Our technology has completed a laboratory prototype, proved to be feasibleworkable. The costenergy consumption are better than the commercial competitors. Now our R&D team further builds the first carbon neutral pilot plant in Taiwan with a continuous process from CO2 capture→purification→alkylation. The pilot plant has successively cooperated with high-carbon industries such as steel, petrochemical,power plants to transform the CO2/CO of flue gas into high-value green chemicals, key agricultural urea fertilizer materialsenergy storage chemicals.

The goal of this project is to study "low-temperature magnesium hydrogen storage materials and energy storage applications". Mg hydrogen storage materials with a hydrogen storage capacity of 5.0 wt% is developed,and their dehydrogenation rate at 250℃ will be significantly enhanced using a forcible pump. The Mg hydrogen storage powders are inserted into a tank for cyclic hydrogenation-dehydrogenation tests. The H2 gas desorbed from the tank is supplied to a high-temperature proton exchange membrane fuel cell (HT-PEMFC,160℃) for power generation.

PPARγ is the master regulator of glucose metabolism.15-keto-PGE2 is an endogenous PPARγ ligand whitch is degraded by ZADH1. We found that increasing 15-keto-PGE2 promotes glucose uptake. We identified several ZADH1 inhibitors which could increase 15-keto-PGE2 promote glucose uptake via activating PPARγ. Our results showed that inhibition of ZADH1 is a novel approach to treat type 2 diabes mell