A semiconductor device includes an integrated circuit that is disposed at a first face side of a semiconductor substrate, the semiconductor substrate having a first face and a second face, the second face opposing the first face, the semiconductor substrate having a through hole from the first face to the second face; an external connection terminal that is disposed at the first face side; a conductive portion that is disposed in the through hole, the conductive portion being electrically connected to the external connection terminal; and an electronic element that is disposed at a second face side.

A semiconductor device includes a semiconductor body having opposite first and second surfaces. The semiconductor device further includes a transistor structure in the semiconductor body and a source contact structure overlapping the transistor structure. The source contact structure is electrically connected to source regions of the transistor structure. A gate contact structure is further provided, which has a part separated from the source contact structure by a longitudinal gap within a lateral plane. Gate interconnecting structures bridge the longitudinal gap and are electrically coupled between the gate contact structure and a gate electrode of the transistor structure. Electrostatic discharge protection structures bridge the longitudinal gap and are electrically coupled between the gate contact structure and the source contact structure. At least one of the gate interconnecting structures is between two of the electrostatic discharge protection structures along a length direction of the longitudinal gap.

An electronic component made up of field-effect transistor (FET) cells is disclosed. Each FET cell includes a finger region having drain, gate, and source fingers disposed over a semiconductor substrate. An isolation region extends across a first end of the finger region. An off-state linearization region abuts the first end of the isolation region. A doped well is disposed within the off-state linearization region over the semiconductor substrate. A dielectric layer is disposed over the doped region. A first conductive stripe is disposed over the dielectric layer in longitudinal alignment with the drain finger. A second conductive stripe is disposed over the dielectric layer in longitudinal alignment with the drain finger. A drain finger electrode is aligned over and coupled to both the drain finger and the first conductive stripe. A source finger electrode is aligned over and coupled to both the source finger and the second conductive stripe.

A chip structure including a chip and a redistribution layer is provided. The chip includes a plurality of pads. The redistribution layer includes a dielectric layer and a plurality of conductive traces. The dielectric layer is disposed on the chip and has a plurality of contact windows located above the pads. The conductive traces are located on the dielectric layer and are electrically coupled to the pads through the contact windows. At least one of the conductive traces includes a body and at least one protrusion coupled to the body, and the at least one protrusion is coupled to an area of the body other than where the contact windows are coupled to on the body.

A silicon carbide semiconductor device includes a gate insulating film and a gate electrode. A first main surface is provided with a trench defined by a side surface penetrating a third impurity region and a second impurity region to reach a first impurity region, and a bottom provided continuously with the side surface. In a stress test in which a gate voltage of at least one of 10 V and 20 V is applied to the gate electrode for 100 hours at a temperature of 175 C., where a threshold voltage before the stress test is defined as a first threshold voltage and a threshold voltage after the stress test is defined as a second threshold voltage, an absolute value of a difference between the first threshold voltage and the second threshold voltage is not more than 0.25 V. The second threshold voltage is not less than 2.5 V.

A multi-finger transistor includes a circuit suppressing a variation in voltage current distribution. The circuit connects gate fingers (21) to each other, or source fingers (31) to each other in a region which is located outside an active region (11) and on a side where a drain pad (42) is disposed. The multi-finger transistor is configured to be linearly symmetric with respect to a direction of propagation of a signal from a gate pad (22) at the position of the gate pad (22).

Devices are formed to have inner layers that have electronic devices, and an outer passivation layer. A patterned conductor is formed on a first surface of the inner layers, and through conductors (that extend through interior insulator layers) are positioned to electrically connect the patterned conductor to the electronic devices. The patterned conductor includes a pattern of connected linear sections that are parallel to the first surface of the inner layers. The linear sections of the patterned conductor meet at conductor corners, and at least one of the conductor corners of the patterned conductor includes a chamfer side that terminates at the linear sections. Further, the chamfer side is not perfectly diagonal, but instead forms unequal angles with the linear sections that intersect to form the corner.

A semiconductor device includes a plurality of unit cell transistors on a common semiconductor structure, the unit cell transistors electrically connected in parallel, and each unit cell transistor including a respective gate finger. Respective threshold voltages of first and second of the unit cell transistors differ by at least 0.1 volts and/or threshold voltages of first and second segments of a third of the unit cell transistors differ by at least 0.1 volts.

A system and method for forming a semiconductor die contact structure is disclosed. An embodiment comprises a top level metal contact, such as copper, with a thickness large enough to act as a buffer for underlying low-k, extremely low-k, or ultra low-k dielectric layers. A contact pad or post-passivation interconnect may be formed over the top level metal contact, and a copper pillar or solder bump may be formed to be in electrical connection with the top level metal contact.

A semiconductor device according to one embodiment includes: a semiconductor substrate having a first surface and a second surface which is an opposite surface of the first surface; a first wiring and a second wiring disposed on the first surface; a first conductive film electrically connected to the first wiring; and a gate electrode. The semiconductor substrate has a source region, a drain region, a drift region, and a body region. The drift region is disposed so as to surround the body region in a plan view. The first wiring has a first portion disposed so as to extend across a boundary between the drift region and the body region in a plan view, and electrically connected to the drift region. The second wiring is electrically connected to the source region. The first conductive film is insulated from and faces the second wiring.