Abstract: A head-mounted display device is provided. The head-mounted display device includes a sensor and a controller. The sensor is configured to capture an eye image of eyes of a user. The controller is coupled to the sensor and configured to: analyze the eye image to generate an analysis result, wherein the analysis result indicates that whether the eyes in the eye image is clear or not; and in response to the analysis result indicating that the eye in the eye image is not clear, output an issue detected signal.

Abstract: Provided is an electrochromic rearview mirror assembly with a large viewable reflective region, comprising a first portion, a second portion, and an electrochromic medium. The first portion comprises a first substrate and a light-transmitting conductive layer disposed on the first substrate. The second portion comprises a second substrate and a transflective conductive layer disposed on the second substrate. The electrochromic medium is arranged between the first portion and the second portion. The area of the light-transmitting conductive layer of the first portion is greater than that of the electrochromic medium, such that a first conductive region is exposed at a rear side of the light-transmitting conductive layer. The second substrate of the second portion has a through-hole parallel to a viewing direction, such that a second conductive region is exposed at a rear side of the transflective conductive layer.

Abstract: Graphene layers made of primarily sp2 bonded atoms and associated methods are disclosed. In one aspect, for example, a method of forming a graphite film can include heating a solid substrate under vacuum to a solubilizing temperature that is less than a melting point of the solid substrate, solubilizing carbon atoms from a graphite source into the heated solid substrate, and cooling the heated solid substrate at a rate sufficient to form a graphite film from the solubilized carbon atoms on at least one surface of the solid substrate. The graphite film is formed to be substantially free of lattice defects.

Abstract: The present invention discloses a graphene platelet fabrication method, which comprises Step (A): providing a highly-graphitized graphene having a graphitization degree of 0.8-1.0; and Step (B): providing a shear force acting on the highly-graphitized graphene to separate the highly-graphitized graphene into graphene platelets, wherein the graphene platelets have a length of 10-500 ?m and a width of 10-500 ?m and have a single-layer or multi-layer structure. The present invention also discloses a graphene platelet fabricated according to the abovementioned method.

Abstract: Graphene layers made of primarily sp2 bonded atoms and associated methods are disclosed. In one aspect, for example, a method of forming a graphite film can include heating a solid substrate under vacuum to a solubilizing temperature that is less than a melting point of the solid substrate, solubilizing carbon atoms from a graphite source into the heated solid substrate, and cooling the heated solid substrate at a rate sufficient to form a graphite film from the solubilized carbon atoms on at least one surface of the solid substrate. The graphite film is formed to be substantially free of lattice defects.

Abstract: A heat conducting composite material includes a matrix and a graphene sheet. The graphene sheet has a two-dimensional planar structure, and a basal plane of the graphene sheet has a lateral size between 0.1 nm and 100 nm such that the graphene sheet has a quantum well structure. When radiation energy passes through the heat conducting composite material, the radiation energy is converted into infrared light by the quantum well structure of the graphene sheet to achieve high radiating efficiency. A light-emitting diode (LED) having the heat conducting composite material and capable of achieving a heat dissipation effect is further disclosed.

Abstract: A vibratable culture apparatus includes a culture device and a vibrating device having a driving module and a vibrating module. The vibrating module has a working platform connected to the driving module, a plurality of lighting units installed on the working platform, and a plurality of positioning units. The working platform is vibratable in a plane by the driving module. Each lighting unit has a first LED set used and a second LED set. The positioning units are installed on the working platform and respectively arranged adjacent to the lighting units. The culture device is detachably disposed on the working platform and restricted by at least partial the positioning units for maintaining the relative position between the culture device and the working platform. The culture device is arranged above at least partial the lighting units that used for emitting light to penetrate into the culture device.

Abstract: The instant disclosure relates to a manufacturing method of cathode catalyst, comprising the following steps. Initially, mix an organic medium with an iron-based starting material and a nitrogen-based starting material to form a mixture. Followed by adding a carbon material to the mixture and subsequently executing a heating process to form a solid-state precursor. Then mill the solid-state precursor to form a precursory powder. Successively, calcinate the precursory powder in the presence of NH3 to form a cathode catalyst. The cathode catalyst can reduce the activation energy of hydrogen ion reacting with oxygen to make water. The instant disclosure further provides an ozone-generating device.

Abstract: A heat conducting composite material includes a matrix and a graphene sheet. The graphene sheet has a two-dimensional planar structure, and a basal plane of the graphene sheet has a lateral size between 0.1 nm and 100 nm such that the graphene sheet has a quantum well structure. When radiation energy passes through the heat conducting composite material, the radiation energy is converted into infrared light by the quantum well structure of the graphene sheet to achieve high radiating efficiency. A light-emitting diode (LED) having the heat conducting composite material and capable of achieving a heat dissipation effect is further disclosed.

Abstract: The present invention discloses a graphene platelet fabrication method, which comprises Step (A): providing a highly-graphitized graphene having a graphitization degree of 0.8-1.0; and Step (B): providing a shear force acting on the highly-graphitized graphene to separate the highly-graphitized graphene into graphene platelets, wherein the graphene platelets have a length of 10-500 ?m and a width of 10-500 ?m and have a single-layer or multi-layer structure. The present invention also discloses a graphene platelet fabricated according to the abovementioned method.

Abstract: A cell module includes an anode, a cathode and a proton exchange membrane. The anode adheres to one side of the proton exchange membrane while the cathode adheres to the opposite side thereof. The anode comprises a substrate and at least one diamond-like carbon layer covering the substrate. The present disclosure further provides an ozone generator and a method using the same.

Abstract: A thermally-conductive paste comprises a carrier, at least one graphene platelet, and a plurality of packing materials. The graphene platelets and the packing materials are dispersed in the carrier. At least a portion of the packing materials contact the surface of the graphene platelet. The graphene platelet has a very high thermal conductivity coefficient and a characteristic 2D structure and thus can provide continuous and long-distance thermal conduction paths for the thermally-conductive paste. Thereby is greatly improved the thermal conduction performance of the thermally-conductive paste.

Abstract: A method for fabricating patterned graphene structures, which adopts a photolithographic etching process to fabricate patterned graphene structures, comprises steps: providing a substrate; forming a catalytic layer on the substrate; forming a carbon layer on the catalytic layer; heating the carbon layer to a synthesis temperature to form a graphene layer. A photolithographic etching process is performed on the catalytic layer before formation of the carbon layer. Alternatively, a photolithographic etching process is performed on the carbon layer before heating. Alternatively, a photolithographic etching process is performed on the graphene layer after heating. Compared with the laser etching process, the photolithographic etching process is suitable to fabricate large-area patterned graphene structures and has advantages of high productivity and low cost.

Abstract: A thermal conduction device and a method for fabricating the same are disclosed. Firstly, arrange a plurality of diamond particles on a plane according to a predetermined pattern to form a diamond particle monolayer. Next, apply a forming process on a metal material such that the metal material forms a metal matrix wrapping the diamond particles to form a composite body including the diamond particle monolayer embedded in the metal matrix. Next, stack a plurality of the composite bodies and perform a heating process to join the metal matrixes to each other to form the thermal conduction device. The device is characterized in arranging diamond particles on a plane to form a two-dimensional monolayer structure and manufactured via assembling the two-dimensional monolayer structures to form a three-dimensional multilayer structure. By controlling the arrangement of the diamond particles, the thermal conduction device can have superior thermal conduction performance.

Abstract: An annealing method to reduce defects of epitaxial films and epitaxial films formed therewith. The annealing method includes features as follows: apply a pressure ranged from 10 MPa to 6,000 MPa to an epitaxial film grown on a substrate through a vapor phase deposition process and heat the epitaxial film at a temperature lower than the melting temperature of the epitaxial film. Through applying pressure to the epitaxial film, the lattice strain of the epitaxial film is alleviated, and therefore the defect density of the epitaxial film also decreases.

Abstract: A thermal conduction device and a method for fabricating the same are disclosed. Firstly, arrange a plurality of diamond particles on a plane according to a predetermined pattern to form a diamond particle monolayer. Next, apply a forming process on a metal material such that the metal material forms a metal matrix wrapping the diamond particles to form a composite body including the diamond particle monolayer embedded in the metal matrix. Next, stack a plurality of the composite bodies and perform a heating process to join the metal matrixes to each other to form the thermal conduction device. The device is characterized in arranging diamond particles on a plane to form a two-dimensional monolayer structure and manufactured via assembling the two-dimensional monolayer structures to form a three-dimensional multilayer structure. By controlling the arrangement of the diamond particles, the thermal conduction device can have superior thermal conduction performance.

Abstract: Graphene layers made of primarily sp2 bonded atoms and associated methods are disclosed. In one aspect, for example, a method of forming a graphite film can include heating a solid substrate under vacuum to a solubilizing temperature that is less than a melting point of the solid substrate, solubilizing carbon atoms from a graphite source into the heated solid substrate, and cooling the heated solid substrate at a rate sufficient to form a graphite film from the solubilized carbon atoms on at least one surface of the solid substrate. The graphite film is formed to be substantially free of lattice defects.

Abstract: A solution method for preparing indium-tin oxide (ITO) powders is provided. Indium compounds and tin compounds are dissolved in water respectively to form two solution bodies. Some proper additives are added into the solution bodies to form metal hydroxyl compounds with determined composition. After water washing and filtration, proper additives are added into the solution to peptize the solution. During the peptization process, hydrolysis and condensation reactions occurs between different metal hydroxyl compounds. Solvent of the solution is then removed to form high quality nanometer grade ITO powders.

Abstract: A solution method for preparing indium-tin oxide (ITO) powders is provided. Indium compounds and tin compounds are dissolved in water respectively to form two solution bodies. Some proper additives are added into the solution bodies to form metal hydroxyl compounds with determined composition. After water washing and filtration, proper additives are added into the solution to peptize the solution. During the peptization process, hydrolysis and condensation reactions occurs between different metal hydroxyl compounds. Solvent of the solution is then removed to form high quality nanometer grade ITO powders.