Abstract: A bio-resin composition, a bio-resin composite, and a bio-foam material are provided. The bio-resin composition includes a polymer matrix, a toughener, and an antistatic agent. The weight ratio of the polymer matrix to the toughener is between 90:10 and 60:40. Based on the total weight of the polymer matrix and the toughener, the content of the antistatic agent is between 1% and 10%.

Abstract: The present disclosure provides a solid carbon source, including: a plurality of bar-shaped units, each of the bar-shaped units having at least one turning portion which constitutes a position limiting region; and a plurality of gaps formed between any two of the bar-shaped units for a gas or liquid passage, wherein at least one of the bar-shaped units is disposed in the position limiting region of adjacent bar-shaped units, such that the plurality of bar-shaped units are integrated to a frame structure, and each of the bar-shaped units is formed by a composite material having a density of more than 0.9 g/cm3. A bioreactor having the same and a method for wastewater treatment using the same are also provided.

Abstract: The present disclosure provides a modified starch composition. The modified starch composition includes starch with a terminal siloxane having 100 parts by weight, water having 30-70 parts by weight, and a polyol having 5-35 parts by weight. The present disclosure also provides a starch composite foam material and method for preparing the same.

Abstract: A modified cellulose is provided. The modified cellulose is represented by the chemical formula (1): wherein n is between 60 and 2500, at least one R is selected from one of the group consisting of R1 is C11 to C32 alkyl group or C11 to C32 alkenyl group, R2 is hydrogen, C3 to C29 alkyl group or C3 to C29 alkenyl group, R3 is C3 to C29 alkyl group or C3 to C29 alkenyl group, R4 is C4 to C8 cycloalkyl group or C4 to C8 cycloalkenyl group, n2 is between 15 and 33, n4 is between 20 and 40.

Abstract: A modified cellulose is provided. The modified cellulose is represented by the chemical formula (1): wherein n is between 60 and 2500, at least one R is selected from one of the group consisting of R1 is C11 to C32 alkyl group or C11 to C32 alkenyl group, R2 is hydrogen, C3 to C29 alkyl group or C3 to C29 alkenyl group, R3 is C3 to C29 alkyl group or C3 to C29 alkenyl group, R4 is C4 to C8 cycloalkyl group or C4 to C8 cycloalkenyl group, n2 is between 15 and 33, n4 is between 20 and 40.

Abstract: In one embodiment, A flame-retardant thermoplastic starch material, including (A1) 100 parts by weight of starch; (A2) 5 to 75 parts by weight of plasticizer; and (A3) 5 to 30 parts by weight of organic phosphonate flame-retardant, wherein the organic phosphonate flame-retardant has the following formula (I): wherein X is a trivalent aliphatic hydrocarbon radical containing 3 to 12 carbon atoms; R1 and R2 are independently C1 to C8 alkyl; and n is 0 or 1.

Abstract: The present disclosure provides a modified starch composition. The modified starch composition includes starch with a terminal siloxane having 100 parts by weight, water having 30-70 parts by weight, and a polyol having 5-35 parts by weight. The present disclosure also provides a starch composite foam material and method for preparing the same.

Abstract: In one embodiment, A flame-retardant thermoplastic starch material, including (A1) 100 parts by weight of starch; (A2) 5 to 75 parts by weight of plasticizer; and (A3) 5 to 30 parts by weight of organic phosphonate flame-retardant, wherein the organic phosphonate flame-retardant has the following formula (I): wherein X is a trivalent aliphatic hydrocarbon radical containing 3 to 12 carbon atoms; R1 and R2 are independently C1 to C8 alkyl; and n is 0 or 1.

Abstract: In an embodiment, a starch-based thermoplastic composite is provided. The starch-based thermoplastic composite includes thermoplastic starch (TPS), polycarbonate (PC) and acrylonitrile butadiene styrene (ABS), wherein the polycarbonate has a weight ratio of 15-60% in the starch-based thermoplastic composite. The starch-based thermoplastic composite further includes an impact modifier and a compatibilizer.

Abstract: A self-organized nanometer interface structure is disclosed. During the reactive sputtering process, the chemical dynamics difference among reactants induces self-organization to form a special nanometer interface structure. The nanometer interface structure naturally form an interface potential difference so that it has a rectifying effect in a particular range of potential variation range. Therefore, it functions like a diode. Such a self-organized nanometer interface structure can be used in the manufacturing of diodes, transistors, light-emitting devices, and sonic devices. The invention has the advantages of a wide variety of material selections, highly compatible processes, easy operations, and low-cost fabrications.

Abstract: A self-organized nanometer interface structure is disclosed. During the reactive sputtering process, the chemical dynamics difference among reactants induces self-organization to form a special nanometer interface structure. The nanometer interface structure naturally form an interface potential difference so that it has a rectifying effect in a particular range of potential variation range. Therefore, it functions like a diode. Such a self-organized nanometer interface structure can be used in the manufacturing of diodes, transistors, light-emitting devices, and sonic devices. The invention has the advantages of a wide variety of material selections, highly compatible processes, easy operations, and low-cost fabrications.

Abstract: This invention provides a concept of using porous materials on ceramic substrate planarization. This planarized substrate consists of a ceramic substrate, a buffer layer, and a nanostructure layer. The ceramic substrate provides structural strength and surface-mount capability. The buffer layer provides the adhesion between the substrate and the nanostructure layer. The nanostructure layer provides the required surface smoothness of the ceramic substrates for performing thin-film processing techniques and enhances adhesion for metallization and electronic materials.

Abstract: This invention provides a concept of using porous materials on ceramic substrate planarization. This planarized substrate comprises a ceramic substrate, a buffer layer, and a nanostructure layer. The ceramic substrate can enhance the structural strength and surface-mount capability. The buffer layer provides the adhesion between a substrate and a nanostructure layer. Nanostructure layer provides the required surface smoothness of the ceramic substrates for performing thin-film processing techniques and enhancing adhesion for metallization and electronic materials. This layer also provides required properties for integrating electronic such as thermal conductivity, electrical insulation, dielectric, etc.