A method for manufacturing an electrical device is disclosed. In an embodiment, the method includes providing a first layer of a first conductivity type, providing an intrinsic layer onto the first layer, providing one or more trenches into the intrinsic layer, filling the one or more trenches with a material of a second conductivity type opposite to the first conductivity type, and providing a second layer of a second conductivity type onto the intrinsic layer.

First and second output transistors are connected in series between a power supply terminal and a ground terminal through an output node connected to an output terminal. An output transistor control circuit is arranged corresponding to at least one of the first and second output transistors and is configured to input a voltage at the output terminal to the gate of the first output transistor at a time of occurrence of disconnection of the power supply terminal and input the same to the gate of the second output transistor at a time of occurrence of disconnection of the ground terminal. The first output transistor has a conductivity type to turn off when a power supply voltage is input to the gate, and the second output transistor has a conductivity type to turn off when a ground voltage is input to the gate.

Disclosed are systems, devices and methods for utilizing an interconnect conductor to inhibit or reduce the likelihood of de-lamination of a passivation layer of an integrated circuit die. In some implementations, a metal layer in ohmic contact with an intrinsic region of a semiconductor substrate can be partially covered by a passivation layer such as a dielectric layer. An interconnect conductor electrically connected to the metal layer can include an extension that covers an edge of the passivation layer to thereby inhibit the edge from lifting up. In some implementations, the metal layer in combination with a contact pad also in ohmic contact with the intrinsic region can yield a conduction path through the intrinsic region during an electrostatic discharge (ESD) event. In such a configuration, the interconnect conductor can route the ESD charge to a ground.

To provide a semiconductor device having excellent conduction characteristics of a transistor portion and a diode portion. The semiconductor device having a transistor portion and a diode portion, the semiconductor device includes: a drift region of a first conductivity type provided on a semiconductor substrate, a first well region of a second conductivity type provided on an upper surface side of the semiconductor substrate, an anode region of the second conductivity provided on the upper surface side of the semiconductor substrate, in the diode portion, and a first high concentration region of a second conductivity type which is provided in contact with a first well region between the anode region and the first well region, and has a higher doping concentration than the anode region.

A first region is formed by injecting a first condition type first dopant into a surface layer portion of an IGBT section of a semiconductor substrate. A second region is formed by injecting a second condition type second dopant into a region of the IGBT section shallower than the first region. An amorphous third region is formed by injecting the first conduction type third dopant into a surface layer portion of a diode section at a concentration higher than that of the second dopant. Thereafter, the IGBT section and the diode section are laser-annealed under conditions in which the third region is partially melted and the first dopant is activated. Subsequently, a surface layer portion which is shallower than the second injection region in the entire region of the IGBT section and the diode section is melted and crystallized by annealing the IGBT section and the diode section.

Proton irradiation is performed a plurality of times from rear surface of an n-type semiconductor substrate, which is an n.sup.− drift layer, forming an n-type FS layer having lower resistance than the n-type semiconductor substrate in the rear surface of the n.sup.− drift layer. When the proton irradiation is performed a plurality of times, the next proton irradiation is performed to as to compensate for a reduction in mobility due to disorder which remains after the previous proton irradiation. In this case, the second or subsequent proton irradiation is performed at the position of the disorder which is formed by the previous proton irradiation. In this way, even after proton irradiation and a heat treatment, the disorder is reduced and it is possible to prevent deterioration of characteristics, such as increase in leakage current. It is possible to form an n-type FS layer including a high-concentration hydrogen-related donor layer.

A semiconductor element capable of adjusting a barrier height φ.sub.Bn and performing zero-bias operation and impedance matching with an antenna for improving detection sensitivity of high-frequency RF electric signals, a method of manufacturing the same, and a semiconductor device having the same. In the semiconductor element, a concentration of InGaAs (n-type InGaAs layer) is intentionally set to be high over a range for preventing the “change of the barrier height caused by the bias” described above up to a deep degeneration range. An electron Fermi level (E.sub.F) increases from a band edge of InGaAs (n-type InGaAs layer) to a band edge of InP (InP depletion layer).

A semiconductor system including a planar anode contact, a planar cathode contact, and a volume of n-conductive semiconductor material, which has an anode-side end and a cathode-side end and extends between the anode contact and the cathode contact. A p-conductive area extends from the anode-side end of the volume toward the cathode-side end of the volume without reaching the cathode-side end. The p-conductive area has two sub-areas which are separated from one another in a cross section lying transversely with respect to the anode contact and the cathode contact, which delimit a sub-volume of the volume filled with n-conductive semiconductor material. The sub-volume is open toward the cathode contact, and is delimited by cathode-side ends of the sub-areas. A distance of the two sub-areas defining the opening is smaller than a distance between the two sub-areas prevailing outside of the opening and lying between anode side ends of the sub-areas.

A test device includes a diode junction layer having a first dopant conductivity region and a second dopant conductivity region formed within the diode junction layer on opposite sides of a diode junction. A first portion of vertical transistors is formed over the first dopant conductivity region as a device under test, and a second portion of vertical transistors is formed over the second dopant conductivity region. A common source/drain region is formed over the first and second portions of vertical transistors. Current through the first portion of vertical transistors permits measurement of a resistance at a probe contact connected to the common source/drain region.

A semiconductor device includes a first semiconductor region of a first conductivity type on a first electrode and a second semiconductor region of the first conductivity type on a central portion of the first semiconductor region. The second region has a carrier concentration less than a carrier concentration of the first region. A third semiconductor region of a second conductivity type is on the second semiconductor region. A first insulating portion covers a peripheral surface of the second semiconductor region and a peripheral surface of the third semiconductor region. A second insulating portion is spaced from the first insulating portion in a lateral direction. A void space is between the first and second insulating portions. A third insulating portion is on the third semiconductor region and spans and covers the void space. A second electrode is on the third semiconductor region and the third insulating portion.