Through the study of structural biological materialthe multiscale analysissimulation, we construct an initiative integrated platform, which provides user-friendly experience, automatically generates designs of lightweight structure for the demandsoffers various choices of materialssuggestions. This design platform contains great potential for engineering applications.

The self-healing ultra-high-performance concrete is a green construction material. It has the key characteristics of self-healing ability, high deformability, and ultra-high strength. The material composition contains a high proportion of by-products from industrial manufacturing. The particle packing density of the developed material is optimized to make this new multi-functional concrete material also have the ability of self-healing and deformability.

The performance of Li-ion batteries mainly depends on electrode active material properties. However, the advanced characterization of obtaining the essential electrode materials properties is extremely required for electrode materials R&D. We developed the world＇s first single-particle electrode measurement, which shows precise electrochemical measurements of obtaining the essential electrode materials properties. Single-particle electrode measurement will become the vital characterization technology for electrode materials R&D in Li-ion batteries as well as advanced rechargeable batteries.

Inorganic porous nanofibers with surfaceinterface defects are prepared through humidity-controlled electrospinninghigh-temperature annealing technology. Under the irradiation of light sources of different wavelengths (380~780 nm), the bound electrons stored in the valence band can be excited to the conduction band to form free electrons on the surface of the material, generating different intensities of microcurrents, light sensitivitymicrocurrent changes. Because the "inorganic nanofiber" technology has high uniquenesshigh product compatibility, it can be applied to a wide range of markets.

Inorganic porous nanofibers with surfaceinterface defects are prepared through humidity-controlled electrospinninghigh-temperature annealing technology. Under the irradiation of light sources of different wavelengths (380~780 nm), the bound electrons stored in the valence band can be excited to the conduction band to form free electrons on the surface of the material, generating different intensities of microcurrents, light sensitivitymicrocurrent changes. Because the "inorganic nanofiber" technology has high uniquenesshigh product compatibility, it can be applied to a wide range of markets.

Using the concept of bionicscircular economy to develop low-costhigh -performance flexible electrodesionic liquid polyelectrolytes for all solid-state flexible supercapacitors. This type of flexible electrode has excellent dimensional stabilityelectrochemical characteristics. The gel-state polyelectrolytes can be used with metal oxide electrodes to provide high scalability, low cost,high efficiency at high temperatures.

The red-leaf aglaonema were promoted growth of by water-retaining materials. For the growers, the technology can effectively shorten the duration of cultivationpromote the quality of potted flower. Therefore, the technology solves the problems of productionwill have practical application in the industry.

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.

The smart graphene (Gr) sensor developed by this team is self-assembly arranged through Gr. No traditional polarization process is further required due to use of high conductivity of Gr. Further, because of the conductivity of the Gr sensor itself, no additional electrodes are required for collecting the mechanical-electric signals.The process of manufacturing the piezoelectric film can be simplifiedthe cost of process reduced. Moreover, the Gr sensor can be directly coated on materials with different curved shapes and, the sensitivity of the direct-coated sensor can be greatly enhanced.

Based on the mass production technique to fabricate 2D materials developed by our group, efficient gas sensors against NOx with sensitivity of 100 ppb are successfully demonstrated. In comparison to international competitors, our products exhibit superior sensitivityselectivity. Furthermore, the technique would be extended to other 2D materials to fabricate various gas sensors against multiple target gases. The integration with internet of things would then open new feasibilities for early monitoring in environmental pollutionhuman safety.

Gene delivery technology is widely used in cell therapy, nucleic acid-based vaccines, protein production, gene therapy, etc. We have developed a non-viral gene delivery technology-MPGene, which has excellent gene delivery efficiency (50-80) for human mesenchymal stem cells,also has the characteristics of low production costhigh safety. In the future, MPGene has the potential to be used in important biomedical fields such as gene delivery reagents, major trauma cell therapy, malignant tumor treatmentcartilage cell therapy.

Based on the optical fluorescence of the plant, the technology distinguishes the difference of the main protein infected by virus from the normal ones with the feature light. The main difference of this technology is to omit the complicatedbiochemical-material- consumption procedures. With the establishment of big data, the artificial intelligence algorithm identifies whether the implant is.

(1) Ｇel-type solid electrolytes and All solid-state electrolytes for Lithium Ion Battery (LIBs) (2) Fabrication of dye-sensitized solar cells by printing process and its applications on Internet-of-Things (IoT) - MOST 2019 Award (3) Silicon-carbon coating anode materials for LIBs: SiLican startup company growth and global business layout (4) Power enhanced Intermediate Temperature Solid State Fuel Cell (SOFC) (5) Worldwide highest conversion efficiency (19.4%) perovskite solar cells (6) Industrial linking and Product design : LevioPole and Smart motorcycle suitcase

Novel alloys are composed of five special technologies (1)Development of CALPHAD phase diagram for medium entropy alloys(2)Development of novel lightweight Ti-rich medium entropy alloys with high strengthhigh ductility (YS 950 MPa, TS 1200 MPaEL 30)(3)Heterogeneous structures obtained by the thermomechanical treatment an rapid annealing treatment(4)Tailoring the heterogeneous structures to enhance the mechanical properties (YS 1240 MPa, TS 1510 MPa, 250 MPa·cm3/ga nd EL 25)(5)Commercial productions are produced by these large dimension alloys for further industrial application.

Responding the government’s policy of “circular economy”. The project is to manufacture high value and energy saving construction material (lightweight aggregate) by using Taiwan environmental and industrial waste, such as paper sludge, textile sludge, organic waste solvent from semiconductor industry, and reservoir sludge, etc. Based on fully recyclable concept to create real benefits for domestic ecological environment.

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.

A small organic molecule with multiple redox-active sites shows promise in the development of next-generation electric energy storage systems, especia

mmW 5G/B5G/6GLEO satellites use large active antenna arrays of more than 1000 elements. A number reduction aided by low cost intelligent panels is developed to reduce at least 60 cost. AiPAiM are used to compact the array with reconfigurability at low power losses. The gains are compensated by phase-reconfigurable AiP/AiM to feed smart multi-beam panels of large apertures. It may steer directional beams by operating the active RF modules tightly fed by AiP/AiM based arrays. Tile architecture can be implemented using multiple AiPs/AiMs for flexible array configurations.

We proposedshowed the ferroelectric materials served as a prospective substrate to support TMD to achieve a pn homojunction, as the accumulationdepletion of an inevitably charged mobile carrier occurs in the TMD to screen the polarization field of the FE substrate. This work provides a non-volatile control of TMD dopinga promising way to produce a pn homojunction as a future building block of 2D device applications.

This technology contains two important sub-technologies. The first is the development of ultra-high performance concrete composite materials, mastering the 3D printing related properties,developing printable concrete that can actually be used for printing. The second is the simulation, analysisoptimization technology of the concrete 3D printing process. The infinite element method developed by ourselves is used to simulateanalyze the concrete 3D printing process,the geometric of the object is considered to optimize the printing pathparameters.