Abstract: The present invention provides a fabricating process for forming a flexible substrate, comprising the steps of: providing the substrate which is composed of a top plate and a bottom plate, and then a positive electrode layer and a organic electro-luminescence (EL) layer are formed in sequence on the bottom plate; after that, a same axial downward patterned template is pressed onto the bottom plate for “micro-patterning”, and thus the positive electrode layer and the organic electro-luminescence (EL) layer on the bottom plate are patterned in the same axial; providing a top plate, on which a metal layer as a negative electrode is formed; Similarly, a same axial upper patterned template is pressed onto the top plate for “micro-patterning”, and thus the metal layer on the top plate is patterned in the same axial; finally, superimposing the top plate on the bottom plate so that the axis of patterned positive electrode layer and patterned organic EL layer crisscross with the axis of pattern

Abstract: The present invention is to provide a kind of multilayer microstructure macrocapacitor, wherein on one side of an electrode substrate after it forms slots with an appropriate aspect ratio, sequentially forms a high dielectric layer and a conducting material layer to give a basic composition unit, laminates the conducting material layers of two groups of basic composition unit to form a monolayer microstructure macrocapacitor, and stacking laminates the plural groups of the monolayer microstructure macrocapacitor to obtain a multilayer microstructure macrocapacitor; on two sides of an electrode substrate it forms a basic composition unit of a microstructure macrocapacitor through the process described above, and laminates the plural groups of the monolayer microstructure macrocapacitor to obtain a multilayer microstructure macrocapacitor.

Abstract: The present invention is to provide a kind of a ductile grinding processing technique for the diamond material, wherein it comprises of: after giving a heat energy to heat the diamond material, there gives a force to the heated diamond material, and by giving a heat and a force it is able to proceed a ductile grinding processing technique for the diamond material; for the diamond film to proceed a ductile grinding processing technique comprises of: there gives a heat energy to heat the diamond film, and then grinds the heated diamond material with a grinding wheel, and by use of heating and grinding with a grinding wheel it is able to proceed a ductile grinding processing technique for the diamond material.

Abstract: The present invention relates to a manufacturing method and a structure of organic light-emitting diode display panels. By precisely controlling the position—shape and thickness of the organic light-emitting layer of pixels, the conventional cross talk problem can be solved and a better quality and longer lifetime for the OLED can be obtained. This method is to form a plurality of long grooves on a substrate, then fill the grooves with a conducting material to form a plurality of first electrode lines. A cavity matrix is formed on the first electrodes. Each individual cavity of the cavity matrix corresponds to a pixel. An organic light-emitting layer is filled in the cavities. Repeat the above steps three times, and a red-green-blue three-color organic light-emitting matrix can be obtained. A plurality of second electrode lines are formed on the organic light-emitting layer.

Abstract: A micro-mechanical actuator is disclosed for actuating an object in a micro-electro-mechanical system. One end of the object is flexibly connected a substrate, and another end is flexibly connected to an auxiliary lever which is further connected to an actuating force generator. The auxiliary lever receives an actuating force generated from the actuating force generator to perform a levering operation about a fulcrum. The position of the fulcrum allows an portion of the auxiliary lever connected to the object has a shift larger than a shift of another portion of the auxiliary lever connected to the actuating force generator in response to the actuating force.

Abstract: The invention discloses a micro-structure capacitor formed by joining the metal layer of a multi-porous micro-structure. A substrate is used as an etching stop layer when producing the capacitor. Therefore, pores with low aspect ratio and uniform size are formed on the surface of the substrate. The efficiency of the subsequent thin film coating process is increased. The porous three-dimensional structure increases the capacitance. Micro-structures are stacked up so the capacitor produced features small size and high capacitance.

Abstract: A micro-mechanical actuator is disclosed for actuating an object in a micro-electro-mechanical system. One end of the object is flexibly connected a substrate, and another end is flexibly connected to an auxiliary lever which is further connected to an actuating force generator. The auxiliary lever receives an actuating force generated from the actuating force generator to perform a levering operation about a fulcrum. The position of the fulcrum allows an portion of the auxiliary lever connected to the object has a shift larger than a shift of another portion of the auxiliary lever connected to the actuating force generator in response to the actuating force.

Abstract: This invention is a method for die separation of a wafer by ion implantation, wherein the die spacing is reduced and the die separation precision reaches a sub-micron level. The separated dies are obtained by wafer splitting after heat treatment and have cleavage roughness at a nano-meter level. The process method comprises the steps of: placing a wafer into an ion implanter; implanting gaseous ions into the split lines of said wafer with assistance of a mask; performing heat treatment of said wafer that is to split at the split lines; and completing die separation.

Abstract: An actuating mechanism for rotating a micro-mirror is disclosed. The actuating mechanism includes a first linking rod consisting of a first and a second portions, a second linking rod consisting of a third and a fourth portions, a first fulcrum positioned between the first and second portions, and a second fulcrum positioned at one side of the fourth portion opposite to the third portion. The first and third portions are flexibly connected to a shaft that the micro-mirror rotates with, and the second and fourth portions are coupled to respective actuators. When actuating forces are applied to move the second and fourth portions, the first and third portions are levered to rotate the shaft and thus the micro-mirror due to the effect of the fulcrums.