Select Field
Select Ministry
11 results
This study develops highly active MoS2 nanoflowers with sulfur vacancies as piezocatalysts. Utilizing mechanical energy, it reduces N2 to NH3 (8294.1 μmol L-1 g-1 h-1) in an atmospheric environmentwithout needing an external light source or electricity. The method enhances piezoelectric properties and nitrogen reduction, offering high selectivity similar to electro- and photocatalysis, without the complexity of electrode/electrolyte systems, providing a new green NH3 production alternative.
Future Tech | Green Energy & EnvironmentThe carbon dioxide in the flue gas is first captured and then introduced into the unique global fluidized-bed homogeneous crystallization tank to synthesize the calcium carbonate crystalline particles with a purity of more than 99.5 % and can be recycled as additives in various processes, such as: papermaking rubber, plastics, coatings and other industrial uses. The technology efficiency with a cross-sectional area loading of 960 kg CO2/m2/day is much higher than other technologies.
Future Tech | Green Energy & EnvironmentPresently, finding effective ways to reutilize these space-occupying, stored CO2 has become an urgent priority. High performance electrochemical CO2 converter is found to be an auspicious resolution for transforming CO2 into valuable chemicals (formic acid, CO, C2H4, ethanol, etc.), providing numerous benefits, including high conversion efficiency, low energy consumption, and also the potential for integration with renewable energy sources, enabling the realization carbon-negative goals.
Future Tech | Green Energy & EnvironmentThis technology is the application of non-precious metal "atomic layer thin films" and "low-dimensional nanocomposites" to modify the surfaces of crucial components in water electrolysis hydrogen production and solid-state hydrogen storage, optimizing the efficiency of water splitting and kinetics of (de)hydrogenation reactions. This includes modifying the electrocatalyst electrode and alkaline anion exchange membrane (AEM) for water electrolysis and Mg-based alloy powders for hydrogen storage.
Future Tech | Green Energy & EnvironmentOur team has developed a high-efficiency semi-transparent perovskite solar cell technology that can be integrated with existing Si-based solar cells to enhance the power conversion efficiency per unit area and has achieved significant success in developing a world record with a power conversion efficiency of over 20%. We aim to transfer more technologies to midstream and downstream manufacturers, enhancing Taiwan's competitiveness in the international solar cell market.
Future Tech | Green Energy & EnvironmentLow-cost solid oxide electrolysis cells are prepared based on the concept of material circular economy, aiming to achieve the goal of Power-to-X and promote energy transformation and carbon emission reduction.
Future Tech | Green Energy & EnvironmentThis technology develops a Modular Rundling Microgrid (MRM) solution for enhancing user-side resilience. The MRM architecture integrates multiple small microgrids (MG), enabling them to collaborate and share resources, thus improving energy utilization efficiency and power supply stability. When the main grid experiences a power outage, the core MG dynamically adjusts the topology to ensure continuous power supply to critical loads.
Future Tech | Green Energy & EnvironmentOur colored PET processing method has three sub-technologies: high-efficiency solvent decolorization tech, novel catalyst catalyzed glycolysis tech, and disintegration tech. Sub-3 can greatly enhance the treatment efficiency of sub-1 and sub-2. By using our processing method, waste colored PET materials can be converted to decolorized PET materials for mechanical recycling while to bis(2-hydroxyethyl) terephthalate (BHET) for PET synthesis production line.
Future Tech | Green Energy & EnvironmentThis technology utilizes the Pulsed Laser Irradiation Scanning on Mixed Salt Solutions method to develop a non-precious metal catalyst based on a Ni-Fe-Mn ternary alloy on metal porous materials, forming porous electrode structures. When applied to Anion Exchange Membrane Water Electrolyzers, it exhibits excellent performance. The technology is simple to operate, cost-effective, and fast to produce, enabling the rapid production of large-area, high-performance catalyst-coated porous electrodes.
Future Tech | Green Energy & EnvironmentUsing bio-concrete to cultivate nano zinc oxide endows it with exceptional properties: Enhanced Strength: Nano zinc oxide and CaCO3 improves concrete's mechanical strength. Photocatalytic: It decomposes air pollutants, purifying air and offering self-cleaning. Hydrophobic: Reduces water penetration, decreasing bacteria and fungi growth. Antimicrobial: Hydroxyl radicals from photocatalysis damage viruses, bacteria, and fungi. Self-Healing: Repairs micro-cracks, extending concrete lifespan.
Future Tech | Green Energy & EnvironmentThis technology uses automatic speech recognition (ASR) and ultrasonic non-destructive testing (NDT) to accurately assess the state of health (SoH) and internal condition (electrolyte and by-product content) of the lithium-ion batteries of electric vehicles. The accuracy of SoH prediction exceeds 93%. The reliability and functionality of this technology surpass international commercial technologies. With the novel AI model and NDT method, this technology will be patented in various countries.
Future Tech | Green Energy & EnvironmentComing soon!
