The present disclosure relates to semiconductor components. The teachings thereof may be embodied in a lead frame for a semiconductor component including: a frame having a recess; an electrically conductive connecting element for establishing an electrical connection to the semiconductor component arranged in the recess; and an insulating element arranged in the recess and mechanically connecting the connecting element to the frame and electrically insulating it from the frame.

A semiconductor device includes a first lead portion and a second lead portion spaced from each other in a first direction. A semiconductor chip is mounted to the first lead portion. A first connector has a first portion contacting a second electrode on the chip and a second portion connected to the second lead portion. A second connector has third portion that contacts the second electrode, but at a position further away than the first portion, and a fourth portion connected to the second portion. At least a part of the second connector overlaps a part of the first connector between the first lead portion and the second lead portion.

A semiconductor device includes a lead frame; a circuit board located on the lead frame; a power device that includes a switching element and is mounted on the circuit board via a bump located between the power device and the circuit board; and a heat releasing member connected to the power device. The circuit board may be a multi-layer wiring board. The circuit board may include a capacitor element, a resistor element, an inductor element, a diode element and a switching element.

A semiconductor device includes: a semiconductor chip; and an Ag fired cap formed so as to cover a source pad electrode formed on the semiconductor chip. The semiconductor chip is disposed on a first substrate electrode, and one end of a Cu wire is bonded onto the Ag fired cap by means of an ultrasonic wave. There is provided a semiconductor device capable of improving a power cycle capability, and a fabrication method of such a semiconductor device.

A second lead frame is set onto a conductive layer and a busbar. The second lead frame has holes previously formed at opposite ends thereof, and pieces of solder material or solder pieces are inserted into the holes. Then, the solder pieces are vibrated by an ultrasonically vibrating tool, whereby the solder pieces are melted without having a high temperature. The second lead frame is thus bonded to the conductive layer and the busbar. A semiconductor element and the busbar are connected by a first lead frame and the second lead frame. The connection structure thereof is such that the second lead frame to be bonded by ultrasonic bonding or other bonding methods is not directly in contact with the semiconductor element, which eliminates the risk of damage to the semiconductor element.

A bonding structure and a method for bonding components, wherein the bonding structure includes a nanoparticle preform. In accordance with embodiments, the nanoparticle preform is placed on a substrate and a workpiece is placed on the nanoparticle preform.

A semiconductor device includes: an insulating circuit substrate; a semiconductor element including a first main electrode bonded to a first conductor layer of the insulating circuit substrate via a first bonding material, a semiconductor substrate deposited on the first main electrode, and a second main electrode deposited on the semiconductor substrate; and a resistive element including a bottom surface electrode bonded to a second conductor layer of the insulating circuit substrate via a second bonding material, a resistive layer with one end electrically connected to the bottom surface electrode, and a top surface electrode electrically connected to another end of the resistive layer, wherein the first main electrode includes a first bonded layer bonded to the first bonding material, the bottom surface electrode includes a second bonded layer bonded to the second bonding material, and the first bonded layer and the second bonded layer have a common structure.

A semiconductor power device is disclosed. The semiconductor power device comprises a lead frame unit, two or more pluralities of single in-line leads, two or more semiconductor chip stacks, and a molding encapsulation. Each semiconductor chip stack includes a high-side semiconductor chip, a low-side semiconductor chip and a clip connecting a top surface of the high-side semiconductor chip to a bottom surface of the low-side semiconductor chip. This invention further discloses a method for fabricating semiconductor power devices. The method comprises the steps of providing a lead frame strip having a plurality of lead frame units; providing two or more pluralities of single in-line leads; attaching two or more high-side semiconductor chips to each lead frame unit; connecting each of the two or more high-side semiconductor chips to a respective lead by a respective clip of two or more first clips; attaching a respective low-side semiconductor chip of the two or more low-side semiconductor chips to each clip of the two or more first clips; molding an encapsulation; and singulating the lead frame strip and the encapsulation to form the semiconductor power devices.

Provided is a semiconductor device stabilizing bond properties between an electrode terminal provided on a case and an internal wiring connected to a semiconductor element. A semiconductor device includes a base part, a semiconductor element, an electrode terminal, an insulating block, and an internal wiring. The semiconductor element is mounted on the base part. The electrode terminal is held by a case surrounding an outer periphery of the semiconductor element. An end portion of the electrode terminal protrudes toward an inner side of the case. The insulating block is provided on the base part between the semiconductor element and the case. In the internal wiring, one end portion is bonded to the end portion of the electrode terminal on the insulating block, and part of a region extending from the one end portion to the other end portion is bonded to the semiconductor element.

A laser welding machine includes: an elevator that is capable of sliding an elevating platform; a pressing actuator that is fixed to the elevating platform at a base part of the pressing actuator and has a tip slidably connected to the base part and pressing a conductive upper terminal toward a conductive lower terminal; a laser oscillator; a machining optical device that is fixed to the elevating platform and has a lens to focus the laser light emitted from the laser oscillator; a position detector that detects a vertical positioning of the pressing actuator; a counter that receives an output of the position detector and delivers position information; and a control circuit that controls, based on the received signal from the counter, the elevator, the pressing actuator, and the machining optical device, and controls operation of the laser oscillator.