Abstract: The disclosure relates to an optical transceiver and a manufacturing method thereof. The optical transceiver includes a substrate, a thermal-conductive substrate, a first metal wiring structure, a light-transceiving element and an optical fiber array. The substrate has an opening, and the thermal-conductive substrate is embedded within the opening. The first metal wiring structure is integrally formed on the substrate and the thermal-conductive substrate through an electroplating or a wire-printing process. The light-transceiving element is disposed on the thermal-conductive substrate and is electrically connected to the first metal wiring structure. The optical fiber array is arranged on the thermal-conductive substrate for communication with the light-transceiving element.

Abstract: The disclosure relates to an optical transceiver and a manufacturing method thereof. The optical transceiver includes a substrate, a thermal-conductive substrate, a first metal wiring structure, a light-transceiving element and an optical fiber array. The substrate has an opening, and the thermal-conductive substrate is embedded within the opening. The first metal wiring structure is integrally formed on the substrate and the thermal-conductive substrate through an electroplating or a wire-printing process. The light-transceiving element is disposed on the thermal-conductive substrate and is electrically connected to the first metal wiring structure. The optical fiber array is arranged on the thermal-conductive substrate for communication with the light-transceiving element.

Abstract: A metal-ion battery is provided. The metal-ion secondary battery includes a first chamber, a second chamber, and a control element. A positive electrode, a negative electrode, a separator disposed between the positive electrode and the negative electrode, and a first electrolyte are disposed within the first chamber. A second electrolyte is disposed within the second chamber, and wherein components and/or concentration of the first electrolyte are different from those of the second electrolyte. The control element determines whether to introduce the second electrolyte disposed within the second chamber into the first chamber via a first pipeline.

Abstract: A metal-ion secondary battery is provided. The metal-ion secondary battery includes a positive electrode. The positive electrode includes at least one current-collecting layer and at least one active layer, wherein the current-collecting layer and the active layer are mutually stacked, and the current-collecting layer has at least one first through-hole.

Abstract: An electrode and a device employing the same are provided. The electrode includes a main body, and an active material. The main body includes a cavity and is made of a conductive network structure. In particular, the active material is disposed in the cavity, wherein the length of the longest side of the particle of the active material is greater than the length of the longest side of the pore of the conductive network structure such that the active material is confined in the conductive network structure.

Abstract: A metal-ion battery is provided. The metal-ion secondary battery includes a positive electrode, a first negative electrode, a first separator, a second negative electrode, a second separator, and a control element, wherein the first separator is disposed between the positive electrode and the first negative electrode, and the second separator is disposed between the first negative electrode and the second negative electrode. Furthermore, the control element is coupled to the first negative electrode and the second negative electrode, wherein the control element determines whether to electrically connect the first negative electrode to the second negative electrode.

Abstract: A metal-ion battery are provided. The disclosure provides a metal-ion battery. The metal-ion battery includes a positive electrode; a negative electrode, wherein the negative electrode is a metal or an alloy thereof, the metal is Cu, Fe, Zn, Co, In, Ni, Sn, Cr, La, Y, Ti, Mn, or Mo; a separator, wherein the positive electrode is separated from the negative electrode by the separator; and an electrolyte, disposed between the positive electrode and the negative electrode. The electrolyte includes ionic liquid, aluminum halide.

Abstract: An electrode and a device employing the same are provided. The electrode can include a metal network structure, and a hollow active material network structure. In particularly, the metal network structure is disposed in the hollow active material network structure. The weight ratio of the metal network structure to the hollow active material network structure is from 0.5 to 155.

Abstract: A metal-ion battery is provided. The metal-ion secondary battery includes a first chamber, a second chamber, and a control element. A positive electrode, a negative electrode, a separator disposed between the positive electrode and the negative electrode, and a first electrolyte are disposed within the first chamber. A second electrolyte is disposed within the second chamber, and wherein components and/or concentration of the first electrolyte are different from those of the second electrolyte. The control element determines whether to introduce the second electrolyte disposed within the second chamber into the first chamber via a first pipeline.

Abstract: An electrode and a device employing the same are provided. The electrode includes a main body, and an active material. The main body includes a cavity and is made of a conductive network structure. In particular, the active material is disposed in the cavity, wherein the length of the longest side of the particle of the active material is greater than the length of the longest side of the pore of the conductive network structure such that the active material is confined in the conductive network structure.

Abstract: A metal-ion secondary battery is provided. The metal-ion secondary battery includes a positive electrode. The positive electrode includes at least one current-collecting layer and at least one active layer, wherein the current-collecting layer and the active layer are mutually stacked, and the current-collecting layer has at least one first through-hole.

Abstract: An electrode, a method for fabricating the same, and a metal ion battery employing the same are provided. The electrode includes a carbon substrate, a metal layer disposed on the carbon substrate, and a crystalline carbon material disposed between the carbon substrate and the metal layer. In particular, the crystalline carbon material is in direct contact with the carbon substrate or the metal layer.

Abstract: A metal-ion battery and a method for preparing the same are provided. The metal-ion battery includes a positive electrode, a separator, a negative electrode, and an electrolyte. The positive electrode is separated from the negative electrode via the separator, and the electrolyte is disposed between the positive electrode and the negative electrode. In particular, the electrolyte includes an ionic liquid, an aluminum halide, and a metal halide, wherein the metal halide is silver halide, copper halide, cobalt halide, ferric halide, zinc halide, indium halide, cadmium halide, nickel halide, tin halide, chromium halide, lanthanum halide, yttrium halide, titanium halide, manganese halide, molybdenum halide, or a combination thereof.

Abstract: A metal-ion battery is provided. The metal-ion secondary battery includes a positive electrode, a first negative electrode, a first separator, a second negative electrode, a second separator, and a control element, wherein the first separator is disposed between the positive electrode and the first negative electrode, and the second separator is disposed between the first negative electrode and the second negative electrode. Furthermore, the control element is coupled to the first negative electrode and the second negative electrode, wherein the control element determines whether to electrically connect the first negative electrode to the second negative electrode.

Abstract: A metal-ion battery are provided. The disclosure provides a metal-ion battery. The metal-ion battery includes a positive electrode; a negative electrode, wherein the negative electrode is a metal or an alloy thereof, the metal is Cu, Fe, Zn, Co, In, Ni, Sn, Cr, La, Y, Ti, Mn, or Mo; a separator, wherein the positive electrode is separated from the negative electrode by the separator; and an electrolyte, disposed between the positive electrode and the negative electrode. The electrolyte includes ionic liquid, aluminum halide.

Abstract: A thermoelectric conversion device and a selective absorber film are provided. The thermoelectric conversion device includes at least one first selective absorber film, a cold terminal substrate, at least one first thermoelectric element pair, a first conductive substrate and a second conductive substrate. The first selective absorber film non-contactly absorbs a preset limited wavelength band of heat radiation. The first thermoelectric element pair is disposed between the first selective absorber film and the cold terminal substrate, and includes a first N-type thermoelectric element and a first P-type thermoelectric element. The first conductive substrate is disposed between the cold terminal substrate and the first N-type thermoelectric element. The second conductive substrate is disposed between the cold terminal substrate and the first P-type thermoelectric element.

Abstract: A graphene thin film with folded configuration including a plurality of sheet layers is provided. Any two adjacent sheet layers are separated by a distance. Each of the sheet layers has a first side and a second side corresponding to the first side. At least one first connecting portion and at least one second connecting portion are alternately arranged on both sides of the sheet layers. One of the at least one first connecting portions connects the first side of an Nth sheet layer and the first side of the (N?1)th sheet layer, and one of the at least one second connecting portions connects the second side of the Nth sheet layer and the second side of the (N+1)th sheet layer. The sheet layers, the at least one first connecting portion, and the at least one second connecting portion form a continuous graphene thin film.

Abstract: A thermoelectric conversion device and a selective absorber film are provided. The thermoelectric conversion device includes at least one first selective absorber film, a cold terminal substrate, at least one first thermoelectric element pair, a first conductive substrate and a second conductive substrate. The first selective absorber film non-contactly absorbs a preset limited wavelength band of heat radiation. The first thermoelectric element pair is disposed between the first selective absorber film and the cold terminal substrate, and includes a first N-type thermoelectric element and a first P-type thermoelectric element. The first conductive substrate is disposed between the cold terminal substrate and the first N-type thermoelectric element. The second conductive substrate is disposed between the cold terminal substrate and the first P-type thermoelectric element.