Abstract: Microelectronic modules are described. In an embodiment, a microelectronic module includes a module substrate, a chip mounted onto the module substrate, and a semiconductor-based integrated passive device between the chip and the module substrate. The semiconductor-based integrated passive device may include an upper RDL stack-up with thicker wiring layers than a lower BEOL stack-up. The semiconductor-based integrated passive device may be further solder bonded or hybrid bonded with the chip.

Abstract: A method includes: sending a pause frame followed by a migrate frame when a value of one of per-flow buffer usage (FBU) counters (referred to as a counter value) exceeds a pause threshold; stopping dequeuing one of pause egress queues (PEQs) when receiving a pause frame; enqueuing a packet into one of the PEQs when receiving a migrate frame; sending a resume frame followed by a migrate-back frame when a previous counter value exceeds the pause threshold and a current counter value is smaller than a resume threshold; when receiving a resume frame, resuming dequeuing one of the PEQs until empty, and then dequeuing a default egress queue (DEQ); and enqueuing a packet into the DEQ when receiving a migrate-back frame.

Abstract: A semiconductor package and a manufacturing method thereof are provided. A carrier having an adhesion layer is provided. A plurality of chips are disposed on the adhesion layer, wherein an active surface of each chip faces the adhesion layer. A molding compound is formed for encapsulating the chips to form a chip-redistribution encapsulant having a first surface and a second surface, wherein the first surface has a chip area and a peripheral area. The carrier and the adhesion layer are removed, so that the chip-redistribution encapsulant exposes the active surface of each chip. A plurality of solder balls are uniformly formed in the chip area and the peripheral area. The second surface of the chip-redistribution encapsulant is grinded to reduce the thickness of the chip-redistribution encapsulant, wherein the solder balls provide the chip-redistribution encapsulant with a uniform support. The chip-redistribution encapsulant is sawn to form a plurality of packages.

Abstract: A first dielectric layer is formed on a mold having a surface and protruding components and covers the protruding components. At least one electronic component having an active surface, a back surface, and contacts formed on the active surface is disposed on the first dielectric layer. The active surface is faced to the first dielectric layer, and the contacts are corresponding to the protruding components. A second dielectric layer is formed on the first dielectric layer and a carrier is disposed on the back surface of the electronic component. Openings located corresponding to the contacts are further formed within the first dielectric layer by the protruding components in an imprinting step, such that when the mold is removed, the contacts are exposed from the openings.

Abstract: A bumping process and a structure thereof are provided. The bumping process includes the following steps. Firstly, a wafer having a number of pads is provided. Next, a UBM layer is formed on the pad. Then, a conductive first photo-resist layer is coated on the wafer to cover the UBM layer. Next, a second photo-resist layer is coated on the first photo-resist layer. Then, at least a portion of the second photo-resist layer is removed to form an opening above the UBM layer. The first photo-resist layer maintains electric connection with the UBM layer. Next, a solder layer is formed in the opening by electroplating process. Then, the first photo-resist layer and the second photo-resist layer are removed expect the portion of the first photo-resist layer under the solder layer.

Abstract: A method for forming bumps is disclosed. First, a substrate having a surface and an under bump metallurgy layer formed thereon is provided, and a portion of the under bump metallurgy layer is removed thereafter. Next, a mask having a metal layer thereon is disposed over the surface of substrate, in which the mask includes at least one opening for exposing the under bump metallurgy layer. Subsequently, a metal is disposed in the opening and the mask having the metal layer is removed.

Abstract: A wafer structure including a semiconductor substrate, a number of UBM layers and a number of bumps is provided. The semiconductor substrate has an active surface, a number of bonding pads and a passivation layer. The bonding pads are positioned on the active surface of the semiconductor substrate. The passivation layer covers the active surface of the semiconductor substrate and exposes the bonding pads. The UBM layers are respectively arranged on the bonding pads, and each UBM layer includes an adhesive layer, a super-lattice barrier layer and a wetting layer. The adhesion layer is disposed on bonding pads. The super-lattice barrier layer is disposed on the adhesion layer and includes a number of alternately stacked sub-barrier layers and sub-wetting layers. The wetting layer is disposed on the super-lattice barrier layer, and the bump is disposed on the wetting layer.

Abstract: A substrate process for an embedded component is disclosed. A mold having a surface and protruding components protruded from the surface is provided. A first dielectric layer is formed on the surface and covers the protruding components. At least one electronic component having an active surface, a back surface, and contacts formed on the active surface is disposed on the first dielectric layer. The active surface is faced to the first dielectric layer, and the contacts are corresponding to the protruding components. A second dielectric layer is formed on the first dielectric layer and a carrier is disposed on the back surface of the electronic component. Openings are formed on the first dielectric layer by the protruding components in an imprinting step. The openings are corresponding to the contacts. Finally, the mold is removed to form a substrate with an embedded component.

Abstract: A method is disclosed for manufacturing soft shoes, wherein the vamp, the insole and the outsole of the soft shoe are combined integrally, so that the soft shoe has an integrally formed structure, thereby enhancing the aesthetic quality of the soft shoe, and thereby enhancing the lifetime of the soft shoe. In addition, the soft shoe has a protective paint layer coated around the peripheral surface of the insole and the outsole, so that the protective paint layer is distributed around the surface of the soft shoe evenly and smoothly.

Abstract: A flip chip package including a chip structure, a substrate and an under-fill is provided. The chip structure includes a base, a number of pads, a first passivation layer, a second passivation layer and a number of bumps. The pads are formed on the base. The first passivation layer is formed on the base and exposes the pads. The second passivation layer formed on the first passivation layer has a number of first openings and at least a second openings. The first openings are positioned on the pads. The second openings are positioned on the area other than the pads. The width at the bottom of the second opening is larger than the width of the second opening at the top. The bumps are formed on the pads. The substrate has a number of connecting points corresponding to the bumps.

Abstract: A chip structure and a manufacturing method of the same. The chip structure includes a base, a pad, a first passivation layer, a second passivation layer and a bump. The pad is formed on the base. The first passivation layer is formed on the base exposing the pad. The second passivation layer formed on the first passivation layer has a passivation layer opening which is positioned above the pad. The bump is formed on the pad, and a part of the bump is disposed inside the passivation layer opening. The width at the bottom of the passivation layer opening is larger than the width at the top of the passivation layer opening, such that the bump is firmly fixed by the second protection layer.

Abstract: A method for forming bumps is disclosed. First, a substrate having a surface and an under bump metallurgy layer formed thereon is provided, and a portion of the under bump metallurgy layer is removed thereafter. Next, a mask having a metal layer thereon is disposed over the surface of substrate, in which the mask includes at least one opening for exposing the under bump metallurgy layer. Subsequently, a metal is disposed in the opening and the mask having the metal layer is removed.

Abstract: A wafer structure including a semiconductor substrate, a number of UBM layers and a number of bumps is provided. The semiconductor substrate has an active surface, a number of bonding pads and a passivation layer. The bonding pads are positioned on the active surface of the semiconductor substrate. The passivation layer covers the active surface of the semiconductor substrate and exposes the bonding pads. The UBM layers are respectively arranged on the bonding pads, and each UBM layer includes an adhesive layer, a super-lattice barrier layer and a wetting layer. The adhesion layer is disposed on bonding pads. The super-lattice barrier layer is disposed on the adhesion layer and includes a number of alternately stacked sub-barrier layers and sub-wetting layers. The wetting layer is disposed on the super-lattice barrier layer, and the bump is disposed on the wetting layer.

Abstract: A bumping process and a structure thereof are provided. The bumping process includes the following steps. Firstly, a wafer having a number of pads is provided. Next, a UBM layer is formed on the pad. Then, a conductive first photo-resist layer is coated on the wafer to cover the UBM layer. Next, a second photo-resist layer is coated on the first photo-resist layer. Then, at least a portion of the second photo-resist layer is removed to form an opening above the UBM layer. The first photo-resist layer maintains electric connection with the UBM layer. Next, a solder layer is formed in the opening by electroplating process. Then, the first photo-resist layer and the second photo-resist layer are removed expect the portion of the first photo-resist layer under the solder layer.