This application claims the priority benefit of Taiwan application serial no. 109140431, filed on Nov. 19, 2020. The entirety of the above-mentioned patent application is hereby incorporated by reference herein and made a part of this specification.
The disclosure relates to a semiconductor structure and a manufacturing method thereof, and more particularly to a package carrier and a manufacturing method thereof.
In an every layer interconnection count (ELIC) circuit board structure, it is difficult for the circuit layer to have heat dissipation or heat-conducting effects. In order to solve the above-mentioned problem, currently, the heat source is dissipated in a vertical direction (i.e., Z direction) through the methods of 1.) forming thermal pads/bars/x-vias by means of copper electroplating; 2.) embedding copper blocks; and 3.) adopting metal cores. Among the above methods, in the method of forming thermal pads/bars/x-vias by means of copper electroplating, the size of the heat-conducting path is limited by the electroplating ability. Furthermore, embedding copper blocks works based on the theory of conducting heat to the vertical direction through the copper blocks, which is not suitable for a structure in which the thickness of interlayer is too thin. Additionally, in the case of using metal as the material for core layer, although it is possible to achieve heat conduction in horizontal direction, it is required to use blind vias to conduct the heat source to the metal core in the lower layer, which is an indirect contact heat conduction. That is to say, for the multilayer board structure, the vertical heat-conducting path will be blocked by other layers and it is difficult to establish a large-area contact with the outside. Accordingly, the heat source will be limited to the center of the board, resulting in limited heat dissipation.
The disclosure provides a package carrier, which achieves an improved heat-conducting effect.
The disclosure further provides a manufacturing method of a package carrier, which serves to manufacture the above-mentioned package carrier, and can achieve an improved heat-conducting effect.
A package carrier of the disclosure includes a circuit structure layer and a heat-conducting element, a heat-generating element and a package adhesive. The circuit structure layer includes a notch portion. The heat-conducting element includes a first heat-conducting portion and a second heat-conducting portion perpendicularly connected to the first heat-conducting portion. The notch portion exposes the first heat-conducting portion, and an outer surface of the second heat-conduction portion is aligned with a side surface of the circuit structure layer.
In an embodiment of the disclosure, the circuit structure layer includes a circuit substrate. The circuit substrate includes a core layer, a first inner circuit layer, a second inner circuit layer, a first dielectric layer, a first circuit layer, at least one first conductive blind via, a second dielectric layer, a second circuit layer and at least one second conductive blind via. The first inner circuit layer is configured on one side of the core layer. The second inner circuit layer is configured on the other side of the core layer. The first dielectric layer covers the first inner circuit layer. The first circuit layer is disposed on the first dielectric layer. The first circuit layer is electrically connected to the first inner circuit layer through the first conductive blind via. The second dielectric layer covers the second inner circuit layer. The second circuit layer is disposed on the second dielectric layer. The second circuit layer is electrically connected to the second inner circuit layer through the second conductive blind via.
In an embodiment of the disclosure, the first heat-conducting portion of the heat-conducting element and the first circuit layer are located on the same plane.
In an embodiment of the disclosure, the first heat-conducting portion of the heat-conducting element directly contacts the first circuit layer.
In an embodiment of the disclosure, the circuit structure layer further includes a first build-up structure and a second build-up structure. The first build-up structure is disposed on the first circuit layer of the circuit substrate and is electrically connected to the first circuit layer, wherein the first build-up structure includes a notch portion. The second build-up structure is arranged on the second circuit layer of the circuit substrate and is electrically connected to the second circuit layer.
In an embodiment of the disclosure, the first build-up structure includes at least one dielectric layer, at least one circuit layer, and at least one conductive blind via. The dielectric layer is located between the circuit layer and the first circuit layer, and the circuit layer is electrically connected to the first circuit layer through the conductive blind via.
In an embodiment of the disclosure, the second build-up structure includes at least one dielectric layer, at least one circuit layer, and at least one conductive blind via. The dielectric layer is located between the circuit layer and the second circuit layer, and the circuit layer is electrically connected to the second circuit layer through the conductive blind via.
In an embodiment of the disclosure, the circuit structure layer further includes a first insulating protection layer and a second insulating protection layer. The first insulating protection layer is disposed on the first build-up structure and exposes part of the first build-up structure. The second insulating protection layer is disposed on the second build-up structure and exposes part of the second build-up structure.
In an embodiment of the disclosure, the circuit structure layer further includes a conductive via, which at least penetrates the circuit substrate and is electrically connected to the first circuit layer, the first inner circuit layer, the second inner circuit layer and the second circuit layer.
In an embodiment of the disclosure, the material of the heat-conducting element includes copper, conductive metal adhesive or heat-conducting metal adhesive.
The manufacturing method of the package carrier of the disclosure includes the following steps. A circuit substrate is provided, wherein the circuit substrate has a through via. A heat-conducting material layer is electroplated on the circuit substrate, wherein the heat-conducting material layer covers the inner wall of the through via. A first build-up structure and a second build-up structure are respectively formed on two opposite sides of the circuit substrate. The first build-up structure and the second build-up structure cover the circuit substrate and the heat-conducting material layer, and fill the through via completely. Part of the first build-up structure, part of the circuit substrate, part of the heat-conducting material layer, and part of the second build-up structure are removed to expose the remaining heat-conducting material layer, so as to define a heat-conducting element and form a circuit structure layer including a notch portion. The heat-conducting element includes a first heat-conducting portion and a second heat-conducting portion vertically connected to the first heat-conducting portion. The notch portion exposes the first heat-conducting portion, and an outer surface of the second heat-conducting portion is aligned with a side surface of the circuit structure layer.
In an embodiment of the disclosure, the step of providing a circuit substrate includes the following steps. A core layer, a first inner circuit layer and a second inner circuit layer are provided. The first inner circuit layer and the second inner circuit layer are respectively located on two opposite surfaces of the core layer. A first dielectric layer and a first copper layer located on the first dielectric layer are formed on the first inner circuit layer, and a second dielectric layer and a second copper layer located on the second dielectric layer are formed on the second inner circuit layer. A through via is formed to penetrate the first copper layer, the first dielectric layer, the core layer, the second dielectric layer, and the second copper layer.
In an embodiment of the disclosure, the manufacturing method of the package carrier further includes the following steps. Before the heat-conducting material layer is electroplated on the circuit substrate, at least one first blind via and at least one second blind via are formed to respectively expose part of the first inner circuit layer and part of the second inner circuit layer. When the heat-conducting material layer is electroplated on the circuit substrate, the heat-conducting material layer further covers the first copper layer and the second copper layer, and completely fills the first blind via and the second blind via. A patterning process is performed on the heat-conducting material layer, the first copper layer, and the second copper layer, and a first circuit layer and a second circuit layer are formed on the first dielectric layer and the second dielectric layer, respectively.
In an embodiment of the disclosure, the manufacturing method of the package carrier further includes the following steps. Before the first build-up structure and the second build-up structure are formed on the two opposite sides of the circuit substrate, a release film is arranged on part of the first circuit layer. Part of the first build-up structure, part of the circuit substrate, part of the heat-conducting material layer and part of the second build-up structure are removed by means of routing and lifting off the release film.
In an embodiment of the disclosure, the manufacturing method of the package carrier further includes forming a first insulating protection layer and a second insulating protection layer respectively on the first build-up structure and the second build-up structure before removing part of the first build-up structure, part of the circuit substrate, part of the heat-conducting material layer, and part of the second build-up structure.
The manufacturing method of the package carrier of the disclosure includes the following steps. A circuit substrate is provided. The circuit substrate includes a first copper layer and a recess. The first copper layer has an opening, and the opening communicates with the recess. A heat-conducting material layer is printed on the circuit substrate, wherein the heat-conducting material layer completely fills the recess and the opening, and is connected to the first copper layer. A first build-up structure and a second build-up structure are respectively formed on two opposite sides of the circuit substrate. The first build-up structure and the second build-up structure cover the circuit substrate and the heat-conducting material layer. Part of the first build-up structure, part of the circuit substrate, part of the heat-conducting material layer, and part of the second build-up structure are removed to expose the remaining heat-conducting material layer, so as to define a heat-conducting element and form a circuit structure layer including a notch portion. The heat-conducting element includes a first heat-conducting portion and a second heat-conducting portion vertically connected to the first heat-conducting portion. The notch portion exposes the first heat-conducting portion, and an outer surface of the second heat-conducting portion is aligned with a side surface of the circuit structure layer.
In an embodiment of the disclosure, the step of providing the circuit substrate includes the following steps. A core layer, a first inner circuit layer and a second inner circuit layer are provided. The first inner circuit layer and the second inner circuit layer are respectively located on two opposite surfaces of the core layer. A first dielectric layer and a first copper layer located on the first dielectric layer are formed on the first inner circuit layer, and a second dielectric layer and a second copper layer located on the second dielectric layer are formed on the second inner circuit layer. An opening penetrating the first copper layer and a recess penetrating the first dielectric layer, the core layer and part of the second dielectric layer are formed.
In an embodiment of the disclosure, the manufacturing method of the package carrier further includes: before the first build-up structure and the second build-up structure are formed on the two opposite sides of the circuit substrate, a patterning process is performed on the first copper layer and the second copper layer to form a first circuit layer and a second circuit layer, respectively, and the heat-conducting material layer is connected to the first circuit layer.
In an embodiment of the disclosure, the manufacturing method of the package carrier further includes forming a first insulating protection layer and a second insulating protection layer respectively on the first build-up structure and the second build-up structure before removing part of the first build-up structure, part of the circuit substrate, part of the heat-conducting material layer, and part of the second build-up structure.
In an embodiment of the disclosure, the material of the heat-conducting material layer includes conductive metal adhesive or heat-conducting metal adhesive.
Based on the above, in the package carrier of the disclosure, the heat-conducting element includes a first heat-conducting portion and a second heat-conducting portion vertically connected to the first heat-conducting portion. That is to say, the first heat-conducting portion of the heat-conducting element is embedded in the circuit structure layer, and the second heat-conducting portion is attached to one side of the circuit structure layer and is exposed to the outside environment, which can increase the contact area with the outside environment, and thus making the package carrier of the disclosure to have an improved heat dissipation efficiency.
In order to make the above-mentioned features and advantages of the present disclosure more comprehensible, the following examples are described in detail with reference to the accompanying drawings.
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Here, the heat-conducting element 200a includes a first heat-conducting portion 210a and a second heat-conducting portion 220a vertically connected to the first heat-conducting portion 210a, which means that the shape of the heat-conducting element 200a is, for example, an inverted L shape. It should be noted that the first heat-conducting portion 210a here is embodied by a combination of the first copper layer 124 (please refer to
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In detail, the circuit structure layer 100a of this embodiment includes the circuit substrate C, wherein the circuit substrate C includes the core layer 112, the first inner circuit layer 115, the second inner circuit layer 117, the first dielectric layer 122, the first circuit layer 125, the first conductive blind via 123, the second dielectric layer 132, the second circuit layer 135, and the second conductive blind via 133. The first inner circuit layer 115 is configured on one side of the core layer 112. The second inner circuit layer 117 is configured on the other side of the core layer 112. The first dielectric layer 122 covers the first inner circuit layer 115, and the first circuit layer 125 is disposed on the first dielectric layer 122. The first circuit layer 125 is electrically connected to the first inner circuit layer 115 through the first conductive blind via 123. The second dielectric layer 132 covers the second inner circuit layer 117, and the second circuit layer 135 is disposed on the second dielectric layer 132. The second circuit layer 135 is electrically connected to the second inner circuit layer 117 through the second conductive blind via 133. Here, the package carrier 10a further includes a conductive via T, which at least penetrates the circuit substrate C, and is electrically connected to the first circuit layer 125, the first inner circuit layer 115, the second inner circuit layer 117, and the second circuit 135. Specifically, the first heat-conducting portion 210a of the heat-conducting element 200a and the first circuit layer 125 of this embodiment are located on the same plane, and the material of the heat-conducting element 200a is copper, for example.
Furthermore, the circuit structure layer 100a of this embodiment further includes a first build-up structure B1 and a second build-up structure B2. The first build-up structure B1 is disposed on the first circuit layer 125 of the circuit substrate C and is electrically connected to the first circuit layer 125. The first build-up structure B1 includes a notch portion E1. The second build-up structure B2 is disposed on the second circuit layer 135 of the circuit substrate C and is electrically connected to the second circuit layer 135. Here, the first build-up structure B1 includes a dielectric layer 152, a circuit layer 154, and a conductive blind via 153, wherein the dielectric layer 152 is located between the circuit layer 154 and the first circuit layer 125, and the circuit layer 154 is electrically connected to the first circuit layer 125 through the conductive blind via 153. The second build-up structure B2 includes a dielectric layer 162, a circuit layer 164, and a conductive blind via 163. The dielectric layer 162 is located between the circuit layer 164 and the second circuit layer 135, and the circuit layer 164 is electrically connected to the second circuit layer 135 through the conductive blind via 163.
In addition, the circuit structure layer 100a of this embodiment further includes a first insulating protection layer 170 and a second insulating protection layer 180. The first insulating protection layer 170 is disposed on the first build-up structure B1 and exposes part of the first build-up structure B1. The second insulating protection layer 180 is disposed on the second build-up structure B2 and exposes part of the second circuit layer 164 of the second build-up structure B2.
In short, the first heat-conducting portion 210a of the heat-conducting element 200a of this embodiment is embedded in the circuit structure layer 100a, and the heat-generating element 300 can be directly disposed on the first heat-conducting portion 210a or fixed on the first heat-conducting portion 210a through an insulating adhesive layer (not shown), such that the heat generated by the heat-generating element 300 can be transferred to the outside through the second heat-conducting portion 220a. Furthermore, since the second heat-conducting portion 220a of the heat-conducting element 200a is attached to one side of the circuit structure layer 100a and is exposed to the outside, thus increasing the contact area with the outside, and therefore the heat generated by the heat-generating element 300 can be effectively and quickly transferred to the outside; accordingly, the package carrier 10a of this embodiment can have an improved heat dissipation efficiency. In addition, the heat-generating element 300 conducts electricity through the first circuit layer 154 of the first build-up structure B1, and the heat-generating element 300 conducts heat through the heat-conducting element 200a, thereby forming a thermoelectric separation structure.
It must be noted here that the following embodiments adopt the element numbers and part of the content of the foregoing embodiments, wherein the same numbers are adopted to represent the same or similar elements, and the description of the same technical content is omitted. The description of the omitted parts can be derived from the foregoing embodiments, and no further description will be narrated herein.
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In summary, in the package carrier of the disclosure, the heat-conducting element includes a first heat-conducting portion and a second heat-conducting portion vertically connected to the first heat-conducting portion. That is, the first heat-conducting portion of the heat-conducting element is embedded in the circuit structure layer, and the second heat-conducting portion is attached to one side of the circuit structure layer and is exposed to the outside, thereby increasing the contact area with the outside. Therefore, when the heat-generating element is arranged on the first heat-conducting portion of the package carrier, the outer surface of the second heat-conducting portion can be aligned with the side surface of the circuit structure layer and the peripheral surface of the encapsulant, thus the heat generated by the heat-generating element can be effectively and quickly transferred to the outside, so that the package carrier of the disclosure can have an improved heat dissipation efficiency.
Although the present disclosure has been disclosed in the above embodiments, it is not intended to limit the present disclosure, and those skilled in the art can make some modifications and refinements without departing from the spirit and scope of the disclosure. Therefore, the scope of the present disclosure is subject to the definition of the scope of the appended claims.
Number | Date | Country | Kind |
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109140431 | Nov 2020 | TW | national |