Abstract: graphite composite laminated heat-dissipating structure and a manufacturing method thereof are disclosed. The structure includes a metal substrate and a graphite heat-dissipating layer. The metal substrate has a first surface having a roughness ranging between 0.01 and 10 ?m. The graphite heat-dissipating layer is composed of pure graphite and is directly formed on the first surface by means of physical vapor deposition using a carbon sputtering target. The graphite heat-dissipating layer has a thickness ranging between 0.05 and 2 ?m. The manufacturing method includes S1: directly forming a graphite heat-dissipating layer on a first surface of a metal substrate by means of physical vapor deposition using a carbon sputtering target after the metal substrate has received plasma treatment or infrared heating; and S2: stopping the physical vapor deposition when the graphite heat-dissipating layer has a thickness ranging between 0.05 and 2 ?m.

Abstract: Disclosures of the present invention mainly describe an alloy for making trace wires of a touch panel. The alloy consists of a first clapping layer, a copper layer, and a second clapping layer. By applying the alloy as the trace wires of the touch panel, feather-like microstructures are effectively prevented from forming between the trace wires and sensor units of the touch panel. On the other hand, because the alloy is able to completely defense the corrosion attack coming from HNO3-based etchant, the trace wires made of the alloy exhibits an outstanding corrosion resistant during the patterning process of the AgNW-made sensor units. Therefore, during patterning the AgNW-made sensor units, the trace wires can have a large processing window, such that the touch panel is hence able to have a good manufacturing yield rate and possesses an outstanding reliability.

Abstract: A biosensor test strip made in the process without the use of an etchant and its etchant-free fabrication method. A patterned stripping layer is formed onto a substrate and is comprised of a masking region and a hollow region, wherein the hollow region defines a wiring pattern. A metallic film is sputtered onto the masking region of the patterned stripping layer as well as the substrate below the hollow region. The patterned stripping layer is washed off by a non-etchant liquid to remove the masking region and the metallic film thereon. The metallic film on the substrate is remained to form a detection line corresponding to the wiring pattern. A pad layer and a reacting enzyme are formed respectively on the detection line and the substrate. The present invention employs the non-etchant liquid to conduct a removing process so as to form the detection line.

Abstract: A method for fabricating an electrochemical sensing test piece comprises steps: forming an electrode layer on a substrate; etching the electrode layer to reduce the area of the electrode layer to be smaller than the area of the substrate, wherein the electrode layer has a test zone and a reading zone neighboring the test zone; forming an insulation member surrounding the test zone and covering the perimeter of the test zone; forming an enzyme layer on the test zone; and forming an insulation layer on the enzyme layer and the periphery of the reading zone and fabricating the insulation layer to have an opening revealing a portion of the enzyme layer. The insulation member fixes the effective reaction area of the tested material and increases measurement accuracy.

Abstract: A method for fabricating an electrochemical sensing test piece comprises steps: forming an electrode layer on a substrate; etching the electrode layer to reduce the area of the electrode layer to be smaller than the area of the substrate, wherein the electrode layer has a test zone and a reading zone neighboring the test zone; forming an insulation member surrounding the test zone and covering the perimeter of the test zone; forming an enzyme layer on the test zone; and forming an insulation layer on the enzyme layer and the periphery of the reading zone and fabricating the insulation layer to have an opening revealing a portion of the enzyme layer. The insulation member fixes the effective reaction area of the tested material and increases measurement accuracy.

Abstract: A polymer-dispersed liquid crystal light-regulation structure comprises a liquid crystal light-regulation layer, a first anti-infrared light-permeable conductive layer, a second anti-infrared light-permeable conductive layer, a first light-permeable substrate, and a second light-permeable substrate. The first and second anti-infrared light-permeable conductive layers are respectively disposed on two sides of the liquid crystal light-regulation layer. The first and second light-permeable substrates are respectively disposed on sides of the first and second anti-infrared light-permeable conductive layers, which are far away from the liquid crystal light-regulation layer.

Abstract: A polymer-dispersed liquid crystal light-regulation structure comprises a liquid crystal light-regulation layer, a first anti-infrared light-permeable conductive layer, a second anti-infrared light-permeable conductive layer, a first light-permeable substrate, and a second light-permeable substrate. The first and second anti-infrared light-permeable conductive layers are respectively disposed on two sides of the liquid crystal light-regulation layer. The first and second light-permeable substrates are respectively disposed on sides of the first and second anti-infrared light-permeable conductive layers, which are far away from the liquid crystal light-regulation layer.

Abstract: A SATA cable capable of grounding noise, includes a cable body; a lead group embedded in the cable body, having two ends exposed from two ends of the cable body, respectively, and comprising a signal transmitting lead group, a signal receiving lead group, power leads and ground leads, the signal transmitting lead group further comprising a first signal transmitting lead and a second signal transmitting lead, and the signal receiving lead group further comprising a first signal receiving lead and a second signal receiving lead; a first metal shield layer unit disposed on a surface of the cable body; a second metal shield layer unit disposed on another surface of the cable body; and a noise lead embedded in the cable body, electrically connected to ground leads, and having two ends exposed from the cable body to thereby electrically connect with the first metal shield layer unit.

Abstract: A SATA cable capable of grounding noise, includes a cable body; a lead group embedded in the cable body, having two ends exposed from two ends of the cable body, respectively, and comprising a signal transmitting lead group, a signal receiving lead group, power leads and ground leads, the signal transmitting lead group further comprising a first signal transmitting lead and a second signal transmitting lead, and the signal receiving lead group further comprising a first signal receiving lead and a second signal receiving lead; a first metal shield layer unit disposed on a surface of the cable body; a second metal shield layer unit disposed on another surface of the cable body; and a noise lead embedded in the cable body, electrically connected to ground leads, and having two ends exposed from the cable body to thereby electrically connect with the first metal shield layer unit.

Abstract: A SATA hard disk drive connector includes a body connected to a SATA hard disk drive; a signal pin unit disposed at the body and having signal transmitting/receiving pins and first grounding pins; a power pin unit disposed at the body and having power pins and second grounding pins; four micro coaxial cables each having a conducting wire, insulating layer, shielding layer and insulating coating, with the conducting wires connected to the signal transmitting/receiving pins at one end and to an external cable at another end; a first grounding unit disposed at the body and connected to an end of each shielding layer and the first grounding pins; a second grounding unit disposed at the body and connected to the second grounding pins, another end of each shielding layer, and external cable; and an electrical connection unit disposed at the body and connected to power pins and external cable.