Semiconductor chip package array is provided. The semiconductor chip package array includes: a lead frame, chips, an encapsulating layer, and an electroplating layer. The lead frame includes a first surface, a second surface, a plurality of support units arranged in a matrix, first grooves, second grooves, and third grooves. The first grooves are connected to the second grooves to form through holes and the third grooves are connected to adjacent support units of the plurality of support units. The chips are disposed on and electrically connected to the plurality of support units. An encapsulating material encapsulates the chips and at least a portion of the plurality of support units, and fill the first grooves to form the encapsulating layer. The electroplating layer is disposed on the second surface of the lead frame, and extends into the third grooves or into the third grooves and the second grooves.

A semiconductor device, having a substrate including an insulating plate and a circuit board provided on a front surface of the insulating plate. The circuit board has a first disposition area and a second disposition area with a gap therebetween, and a groove portion, of which a longitudinal direction is parallel to the gap, formed in the gap. The semiconductor device further includes a first semiconductor chip and a second semiconductor chip located on the circuit board in the first disposition area and the second disposition area, respectively, and a blocking member located in the gap across the groove portion in parallel to the longitudinal direction in a plan view of the semiconductor device.

A semiconductor device, having a substrate including an insulating plate and a circuit board provided on a front surface of the insulating plate. The circuit board has a first disposition area and a second disposition area with a gap therebetween, and a groove portion, of which a longitudinal direction is parallel to the gap, formed in the gap. The semiconductor device further includes a first semiconductor chip and a second semiconductor chip located on the circuit board in the first disposition area and the second disposition area, respectively, and a blocking member located in the gap across the groove portion in parallel to the longitudinal direction in a plan view of the semiconductor device.

The present invention discloses a high-reliability copper alloy bonding wire for electronic packaging and a preparation method therefor; the bonding wire comprises the following raw material components in percentage by weight: a copper content being 99.75%-99.96%, a tungsten content being 0.01-0.1%, a silver content being 0.01%-0.03%, a scandium content being 0.01%-0.02%, a titanium content being 0.001%-0.03%, a chromium content being 0.001%-0.03%, and an iron content being 0.001%-0.02%. The preparation method therefor comprises: extracting high-purity copper with a purity greater than 99.99%, preparing same as copper alloy ingots, and further preparing same as as-cast copper alloy crude bars, drawing the crude bars to form copper alloy wires, subjecting same to a heat treatment, and then precise drawing, a heat treatment, and cleaning to obtain copper alloy bonding wires of different specifications.

A semiconductor device is provided to reduce thermal fatigue in a junction portion of an external wiring to enhance long-term reliability, where the semiconductor device includes a semiconductor substrate, a transistor portion and a diode portion that are alternately arranged along a first direction parallel to a front surface of the semiconductor substrate inside the semiconductor substrate, a surface electrode that is provided above the transistor portion and the diode portion and that is electrically connected to the transistor portion and the diode portion, an external wiring that is joined to the surface electrode and that has a contact width with the surface electrode in the first direction, the contact width being larger than at least one of a width of the transistor portion in the first direction and a width of the diode portion in the first direction.

A semiconductor device is provided to reduce thermal fatigue in a junction portion of an external wiring to enhance long-term reliability, where the semiconductor device includes a semiconductor substrate, a transistor portion and a diode portion that are alternately arranged along a first direction parallel to a front surface of the semiconductor substrate inside the semiconductor substrate, a surface electrode that is provided above the transistor portion and the diode portion and that is electrically connected to the transistor portion and the diode portion, an external wiring that is joined to the surface electrode and that has a contact width with the surface electrode in the first direction, the contact width being larger than at least one of a width of the transistor portion in the first direction and a width of the diode portion in the first direction.

An object of the present disclosure is to provide a high strength aluminum alloy material having a ribbon shape, which can be an alternative to copper-based materials and iron-based materials having a ribbon shape, and a conductive member, a conductive component, a spring member, a spring component, a semiconductor module member, a semiconductor module component, a structural member and a structural component including the aluminum alloy material. The aluminum alloy material of the present disclosure has an alloy composition containing Mg: 0.2% to 1.8% by mass, Si: 0.2% to 2.0% by mass, and Fe: 0.01% to 1.50% by mass, with the balance being Al and inevitable impurities, wherein the aluminum alloy material has a Vickers hardness (HV) of 90 or more and 190 or less and has a ribbon shape.

Semiconductor chip package array is provided. The semiconductor chip package array includes: a lead frame, chips, an encapsulating layer, and an electroplating layer. The lead frame includes a first surface, a second surface, a plurality of support units arranged in a matrix, first grooves, second grooves, and third grooves. The first grooves are connected to the second grooves to form through holes and the third grooves are connected to adjacent support units of the plurality of support units. The chips are disposed on and electrically connected to the plurality of support units. An encapsulating material encapsulates the chips and at least a portion of the plurality of support units, and fill the first grooves to form the encapsulating layer. The electroplating layer is disposed on the second surface of the lead frame, and extends into the third grooves or into the third grooves and the second grooves.

Semiconductor chip package array is provided. The semiconductor chip package array includes: a lead frame, chips, an encapsulating layer, and an electroplating layer. The lead frame includes a first surface, a second surface, a plurality of support units arranged in a matrix, first grooves, second grooves, and third grooves. The first grooves are connected to the second grooves to form through holes and the third grooves are connected to adjacent support units of the plurality of support units. The chips are disposed on and electrically connected to the plurality of support units. An encapsulating material encapsulates the chips and at least a portion of the plurality of support units, and fill the first grooves to form the encapsulating layer. The electroplating layer is disposed on the second surface of the lead frame, and extends into the third grooves or into the third grooves and the second grooves.

Semiconductor chip package device and semiconductor chip package method are provided. The semiconductor chip package device includes: a lead frame, chips, an encapsulating layer, and an electroplating layer. The lead frame includes a first surface, a second surface, first grooves, second grooves, and third grooves. The first grooves are connected to the second grooves to form through holes and the third grooves disposed at ends of the lead frame. The chips are electrically connected to the lead frame. The encapsulating layer is formed by using an encapsulating material to encapsulate the chips and at least a portion of the lead frame. The first grooves are filled with the encapsulating material. The electroplating layer is disposed on the second surface of the lead frame, and extends into the third grooves or into the third grooves and the second grooves.