Abstract: A connecting assembly for a wearable device, a wearable device, and a wearable apparatus are provided. The connecting assembly includes a first connector, a second connector, and a rotating mechanism. The first connector is configured to connect a housing assembly of the wearable device. The second connector is configured to connect a wearable assembly of the wearable device. The rotating mechanism is connected with the first connector and the second connector respectively. The first connector and the second connector are configured to rotate relative to each other through the rotating mechanism. The first connector is provided with a limiting portion at an end of the first connector away from the rotating mechanism, and the limiting portion is configured to cooperate with the housing assembly to limit movement of the first connector.

Abstract: An inkjet printable ionic conductive ink for producing a touch sensor device is provided. The inkjet printable ionic conductive ink includes a hydrophilic polymer and an ionic salt, a mixture of solvents in which the hydrophilic polymer and the ionic salt are dissolved therein to form a solution, and a surfactant to render the solution inkjet printable. A method of producing the inkjet printable ionic conductive ink is also provided. The method includes dissolving a hydrophilic polymer and an ionic salt in a mixture of solvents to form a solution, and mixing the solution with a surfactant to render the solution inkjet printable. A touch sensor panel comprising the ionic conductive ink and a method of producing the touch sensor panel are also provided.

Abstract: The present invention relates to an elastic conductor with high conductivity and stable electrical performance under stretching. The elastic conductor comprises a matrix material; a plurality of electrically conductive structures embedded in the matrix; and one or more particles embedded in the matrix, wherein the particles are configured to release an electrically conductive material upon stretching of the elastic conductor. In a preferred embodiment, each of the particles comprises a core of the electrically conducting material, such as liquid eutectic gallium indium alloy, and an outer shell surrounding the core, such as gallium oxide.

Abstract: An inkjet printable ionic conductive ink for producing a touch sensor device is provided. The inkjet printable ionic conductive ink includes a hydrophilic polymer and an ionic salt, a mixture of solvents in which the hydrophilic polymer and the ionic salt are dissolved therein to form a solution, and a surfactant to render the solution inkjet printable. A method of producing the inkjet printable ionic conductive ink is also provided. The method includes dissolving a hydrophilic polymer and an ionic salt in a mixture of solvents to form a solution, and mixing the solution with a surfactant to render the solution inkjet printable. A touch sensor panel comprising the ionic conductive ink and a method of producing the touch sensor panel are also provided.

Abstract: The present invention belongs to the field of biotechnology, and particularly relates to a Euglena culture medium and an application thereof. The Euglena culture medium includes the following components: NH4Cl, KH2PO4, MgSO4.7H2O, CaCl2.2H2O, Na2EDTA.2H2O, Fe2(SO4)3, CuSO4.5H2O, ZnSO4.7H2O, Co.(NH3).H2O, MnCl2.4H2O, vitamin B1 and vitamin B12. The pH is adjusted based on the Euglena culture medium of the present invention to achieve the purpose of preconcentrating Euglena cells. In the present invention, the Euglena cells are less ruptured, which improves the concentration efficiency of Euglena cells and reduces the treatment cost.

Abstract: The present invention relates to an elastic conductor with high conductivity and stable electrical performance under stretching. The elastic conductor comprises a matrix material; a plurality of electrically conductive structures embedded in the matrix; and one or more particles embedded in the matrix, wherein the particles are configured to release an electrically conductive material upon stretching of the elastic conductor. In a preferred embodiment, each of the particles comprises a core of the electrically conducting material, such as liquid eutectic gallium indium alloy, and an outer shell surrounding the core, such as gallium oxide.

Abstract: In various embodiments, a stretchable electroluminescent device may be provided. The electroluminescent device may include a first contact structure. The first contact structure may include an ionic conductor layer. The electroluminescent device may also include a second contact structure. The electroluminescent device may additionally include an emission layer between the first contact structure and the second contact structure. The emission layer may be configured to emit light when an alternating voltage is applied between the first contact structure and the second contact structure.

Abstract: In various embodiments, a stretchable electroluminescent device may be provided. The electroluminescent device may include a first contact structure. The first contact structure may include an ionic conductor layer. The electroluminescent device may also include a second contact structure. The electroluminescent device may additionally include an emission layer between the first contact structure and the second contact structure. The emission layer may be configured to emit light when an alternating voltage is applied between the first contact structure and the second contact structure.

Abstract: A flexible electronic device is provided. The flexible electronic device includes a flexible dielectric substrate, a first electrode layer, a second electrode layer, a functional layer, a third electrode layer, and a capping layer. The flexible dielectric substrate has a first surface and an opposing second surface. The first electrode layer is arranged on the first surface of the flexible dielectric substrate. The second electrode layer is arranged on the second surface of the flexible dielectric substrate. The functional layer includes a light emitting layer or an electroactive layer and an electrolyte layer, arranged on the second electrode layer. The third electrode layer is arranged on the functional layer. The capping layer is arranged on the third electrode layer. A method of manufacturing the flexible electronic device is also provided.

Abstract: According to embodiments of the present invention, a method of forming an indium oxide nanowire including copper-based dopants is provided. The method includes providing an indium-based precursor material and a copper-based dopant precursor material, and performing a thermal evaporation process to vapourise the indium-based precursor material and the copper-based dopant precursor material to form an indium oxide nanowire comprising copper-based dopants on a substrate. According to further embodiments of the present invention, an indium oxide nanowire including copper-based dopants and a gas sensor are also provided. According to further embodiments of the present invention, a method of forming a plurality of nanowires including metal phthalocyanine, a nanowire arrangement and a gas sensor are also provided.

Abstract: A flexible electronic device is provided. The flexible electronic device comprises a flexible dielectric substrate having a first surface and an opposing second surface; a first electrode layer arranged on the first surface of the flexible dielectric substrate; a second electrode layer arranged on the second surface of the flexible dielectric substrate; a functional layer comprising or consisting of (i) a light emitting layer or (ii) an electroactive layer and an electrolyte layer, arranged on the second electrode layer; a third electrode layer arranged on the functional layer; and a capping layer arranged on the third electrode layer. A method of manufacturing the flexible electronic device is also provided.

Abstract: A method for automatically identifying an optimal endpoint algorithm for qualifying a process endpoint during substrate processing within a plasma processing system is provided. The method includes receiving sensor data from a plurality of sensors during substrate processing of at least one substrate within the plasma processing system, wherein the sensor data includes a plurality of signal streams from a plurality of sensor channels. The method also includes identifying an endpoint domain, wherein the endpoint domain is an approximate period within which the process endpoint is expected to occur. The method further includes analyzing the sensor data to generate a set of potential endpoint signatures. The method yet also includes converting the set of potential endpoint signatures into a set of optimal endpoint algorithms. The method yet further includes importing one optimal endpoint algorithm of the set of optimal endpoint algorithms into production environment.

Abstract: A method for automatically identifying an optimal endpoint algorithm for qualifying a process endpoint during substrate processing within a plasma processing system is provided. The method includes receiving sensor data from a plurality of sensors during substrate processing of at least one substrate within the plasma processing system, wherein the sensor data includes a plurality of signal streams from a plurality of sensor channels. The method also includes identifying an endpoint domain, wherein the endpoint domain is an approximate period within which the process endpoint is expected to occur. The method further includes analyzing the sensor data to generate a set of potential endpoint signatures. The method yet also includes converting the set of potential endpoint signatures into a set of optimal endpoint algorithms. The method yet further includes importing one optimal endpoint algorithm of the set of optimal endpoint algorithms into production environment.