Abstract: A circuit board structure includes an inner circuit structure and a first build-up circuit structure. The inner circuit structure includes a core layer having an upper surface and a lower surface, a first patterned circuit layer disposed on the upper surface, a second patterned circuit layer disposed on the lower surface and a conductive through hole connecting the first and the second patterned circuit layers. The first build-up circuit structure at least has a cavity and an inner dielectric layer. The inner dielectric layer has an opening connecting the cavity and exposing a portion of the first patterned circuit layer. A hole diameter of the opening is smaller than a hole diameter of cavity. A height difference is between an inner surface of the inner dielectric layer exposed by the cavity and a top surface of the first patterned circuit layer exposed by the opening.

Abstract: A manufacturing method of a circuit board structure is described as follows. An inner circuit structure including a core layer having an upper and an opposite lower surface, a first patterned circuit layer disposed on the upper surface and a second patterned circuit layer disposed on the lower surface is provided. An insulating material layer is formed on a portion of the first patterned circuit layer. A laser resisting layer is formed on at least a portion of the insulating material layer. A release layer is adhered to the laser resisting layer. A build-up process is performed so as to laminate a first and a second build-up circuit structures on the first and the second patterned circuit layers, respectively. A laser ablation process is performed on the first build-up circuit structure so as to form a cavity at least exposing a portion of the upper surface of the core layer.

Abstract: A process for a substrate having a component-disposing area is provided, and includes the following steps. A core layer including a first surface, a metallic layer and a component-disposing area is provided. The metallic layer is disposed on the first surface and patterned to form a patterned metallic layer including pads located in the component-disposing area. A first dielectric layer is formed on the first surface and covers the patterned metallic layer. A laser-resistant metallic pattern is formed on the first dielectric layer and surrounds a projection area of the first dielectric layer. A release film is disposed on the projection area and covers a portion of the laser-resistant metallic pattern within the projection area. A second dielectric layer is formed on the first dielectric layer and covers the release film and the laser-resistant metallic pattern. A first open hole and a plurality of second open holes are formed.

Abstract: A circuit board structure includes an inner circuit structure and a first build-up circuit structure. The inner circuit structure includes a core layer having an upper surface and a lower surface, a first patterned circuit layer disposed on the upper surface, a second patterned circuit layer disposed on the lower surface and a conductive through hole connecting the first and the second patterned circuit layers. The first build-up circuit structure at least has a cavity and an inner dielectric layer. The inner dielectric layer has an opening connecting the cavity and exposing a portion of the first patterned circuit layer. A hole diameter of the opening is smaller than a hole diameter of cavity. A height difference is between an inner surface of the inner dielectric layer exposed by the cavity and a top surface of the first patterned circuit layer exposed by the opening.

Abstract: A circuit board with a heat-recovery function includes a substrate, a heat-storing device, and a thermoelectric device. The heat-storing device is embedded in the substrate and connected to a processor for performing heat exchange with the processor. The thermoelectric device embedded in the substrate includes a first metal-junction surface and a second metal-junction surface. The first metal-junction surface is connected to the heat-storing device for performing heat exchange with the heat-storing device. The second metal-junction surface is joined with the first metal-junction surface, in which the thermoelectric device generates an electric potential by a temperature difference between the first metal-junction surface and the second metal-junction surface.

Abstract: A circuit board with a heat-recovery function includes a substrate, a heat-storing device, and a thermoelectric device. The heat-storing device is embedded in the substrate and connected to a processor for performing heat exchange with the processor. The thermoelectric device embedded in the substrate includes a first metal-junction surface and a second metal-junction surface. The first metal-junction surface is connected to the heat-storing device for performing heat exchange with the heat-storing device. The second metal-junction surface is joined with the first metal-junction surface, in which the thermoelectric device generates an electric potential by a temperature difference between the first metal-junction surface and the second metal-junction surface.

Abstract: A circuit board with a heat-recovery function includes a substrate, a heat-storing device, and a thermoelectric device. The heat-storing device is embedded in the substrate and connected to a processor for performing heat exchange with the processor. The thermoelectric device embedded in the substrate includes a first metal-junction surface and a second metal-junction surface. The first metal-junction surface is connected to the heat-storing device for performing heat exchange with the heat-storing device. The second metal-junction surface is joined with the first metal-junction surface, in which the thermoelectric device generates an electric potential by a temperature difference between the first metal-junction surface and the second metal-junction surface.

Abstract: A circuit board with a heat-recovery function includes a substrate, a heat-storing device, and a thermoelectric device. The heat-storing device is embedded in the substrate and connected to a processor for performing heat exchange with the processor. The thermoelectric device embedded in the substrate includes a first metal-junction surface and a second metal-junction surface. The first metal-junction surface is connected to the heat-storing device for performing heat exchange with the heat-storing device. The second metal-junction surface is joined with the first metal-junction surface, in which the thermoelectric device generates an electric potential by a temperature difference between the first metal-junction surface and the second metal-junction surface.

Abstract: A process for a substrate having a component-disposing area is provided, and includes the following steps. A core layer including a first surface, a metallic layer and a component-disposing area is provided. The metallic layer is disposed on the first surface and patterned to form a patterned metallic layer including pads located in the component-disposing area. A first dielectric layer is formed on the first surface and covers the patterned metallic layer. A laser-resistant metallic pattern is formed on the first dielectric layer and surrounds a projection area of the first dielectric layer. A release film is disposed on the projection area and covers a portion of the laser-resistant metallic pattern within the projection area. A second dielectric layer is formed on the first dielectric layer and covers the release film and the laser-resistant metallic pattern. A first open hole and a plurality of second open holes are formed.

Abstract: A substrate structure having a component-disposing area and a process thereof are provided. The substrate structure having a component-disposing area includes a core layer, a first dielectric-layer, a laser-resistant metallic-pattern and a second dielectric-layer. The core layer includes a first surface, a component-disposing area and a patterned metallic-layer disposed on the first surface and including multiple pads, and the pads are located within the component-disposing area. The first dielectric-layer is disposed on the core layer and includes multiple openings to respectively expose the pads. The laser-resistant metallic-pattern is disposed on the first dielectric-layer and surrounds a projection area of the first dielectric-layer which the component-disposing area is orthogonally projected on.

Abstract: A wiring board structure adapted to carry a heat generating component is provided. The wiring board structure includes a core layer, an active cooler, a dielectric layer and a plurality of conductive vias. The core layer has a cavity penetrating through the core layer. The active cooler includes a cold surface and a hot surface. The active cooler is disposed in the cavity. The dielectric layer covers the core layer and fills a gap between the active cooler and the cavity. The heat-generating component is disposed on an outer surface of the dielectric layer. The conductive vias are disposed in the dielectric layer and connecting the cold surface and the outer surface to connect the heat-generating component and the active cooler. A wiring board structure having an active cooling via is also provided.

Abstract: A substrate structure having a component-disposing area and a process thereof are provided. The substrate structure having a component-disposing area includes a core layer, a first dielectric-layer, a laser-resistant metallic-pattern and a second dielectric-layer. The core layer includes a first surface, a component-disposing area and a patterned metallic-layer disposed on the first surface and including multiple pads, and the pads are located within the component-disposing area. The first dielectric-layer is disposed on the core layer and includes multiple openings to respectively expose the pads. The laser-resistant metallic-pattern is disposed on the first dielectric-layer and surrounds a projection area of the first dielectric-layer which the component-disposing area is orthogonally projected on.