An apparatus is formed. The apparatus includes a stack of semiconductor chips. The stack of semiconductor chips includes a logic chip and a memory stack, wherein, the logic chip includes at least one of a GPU and CPU. The apparatus also includes a semiconductor chip substrate. The stack of semiconductor chips are mounted on the semiconductor chip substrate. At least one other logic chip is mounted on the semiconductor chip substrate. The semiconductor chip substrate includes wiring to interconnect the stack of semiconductor chips to the at least one other logic chip.

A memory device includes first and second chips. The first chip includes a memory cell array disposed on a first substrate, and first metal pads on a first uppermost metal layer of the first chip. The second chip includes peripheral circuits disposed on a second substrate, and second metal pads on a second uppermost metal layer of the second chip, the peripheral circuits operating the memory cell array. A first metal pad and a second metal pad are connected in a first area, the first metal pads being connected to the memory cell array and the second metal pad being connected to the peripheral circuits. A further first metal pad and a further second metal pad are connected in a second area, the further first metal pad being not connected to the memory cell array and the further second metal pad being connected to the peripheral circuits.

The present application discloses a semiconductor chip, an electronic device and an electrostatic discharge (ESD) protection method for an electronic device thereof. The semiconductor chip includes an operation electrical contact, a detection electrical contact, an ESD protection unit, and a logic circuit. The operation electrical contact receives an operation signal. The detection electrical contact receives a chip connection signal. The ESD protection unit is coupled to the operation electrical contact. The logic circuit is coupled to the detection electrical contact, and adjusts capacitance of the ESD protection unit according to a chip connection signal received by the detection electrical contact.

Provided are a package structure and a method of forming the same. The method includes: laterally encapsulating a device die and an interconnect die by a first encapsulant; forming a redistribution layer (RDL) structure on the device die, the interconnect die, and the first encapsulant; bonding a package substrate onto the RDL structure, so that the RDL structure is sandwiched between the package substrate and the device die, the interconnect die, and the first encapsulant; laterally encapsulating the package substrate by a second encapsulant; and bonding a memory die onto the interconnect die, wherein the memory die is electrically connected to the device die through the interconnect die and the RDL structure.

Provided is a semiconductor package having improved signal integrity (SI) and a chip stack structure of a plurality of semiconductor chips. The semiconductor package includes a package substrate, a chip stack structure on the package substrate and including at least two semiconductor chips, and an external connection terminal on a lower surface of the package substrate. A first semiconductor chip arranged uppermost in the chip stack structure is connected to a first bonding pad of the package substrate through a first wire. A second semiconductor chip arranged under the first semiconductor chip in the chip stack structure is connected to a second bonding pad of the package substrate through a second wire. When the first bonding pad is farther from the external connection terminal than the second bonding pad, the external connection terminal is connected to the first bonding pad through a wiring line of the package substrate.

Layouts for data pads on a semiconductor die are disclosed. An apparatus may include circuits, a first edge, a second edge perpendicular to the first edge, a third edge opposite the first edge, and a fourth edge opposite the second edge. The apparatus may also include data pads variously electrically coupled to the circuits. The data pads may include a data pad positioned a first distance from the first edge and a second distance from the second edge. The apparatus may also include dummy data pads electrically isolated from the circuits. The dummy data pads may include a dummy data pad positioned substantially the first distance from the first edge and substantially the second distance from the fourth edge. Associated systems and methods are also disclosed.

A method for fabricating semiconductor device includes the steps of first providing a first substrate having a high-voltage (HV) region and a medium voltage (MV) region and a second substrate having a low-voltage (LV) region and a static random access memory (SRAM) region, in which the HV region includes a HV device, the MV region includes a MV device, the LV region includes a fin field-effect transistor (FinFET), and the SRAM region includes a SRAM device. Next, a bonding process is conducted by using hybrid bonding, through-silicon interposer (TSI) or redistribution layer (RDL) for bonding the first substrate and the second substrate.

A Non Conductive Film (NCF) at least includes a first film layer and a second film layer. A surface of the first film layer is provided with a grid-shaped groove structure, and a depth of each groove of the groove structure is less than a thickness of the first film layer. The second film layer is located in the groove in the surface of the first film layer. The fluidity of the first film layer is greater than the fluidity of the second film layer under the same condition.

This application is directed to a stacked semiconductor device assembly including a plurality of identical stacked integrated circuit (IC) devices. Each IC device further includes a master interface, a channel master circuit, a slave interface, a channel slave circuit, a memory core, and a modal pad configured to receive a selection signal for the IC device to communicate data using one of its channel master circuit or its channel slave circuit. In some implementations, the IC devices include a first IC device and one or more second IC devices. In accordance with the selection signal, the first IC device is configured to communicate read/write data via the channel master circuit of the first IC device, and each of the one or more second IC devices is configured to communicate respective read/write data via the channel slave circuit of the respective second IC device.

A three-dimensional (3D) memory device includes a first semiconductor structure and a second semiconductor structure. A first semiconductor structure includes a first substrate, and a memory array structure disposed on the first substrate. The second semiconductor structure is disposed over the first semiconductor structure, and the second semiconductor structure includes a second substrate, and a peripheral device in contact with the second substrate. The second substrate is formed between the peripheral device and the first semiconductor structure.