A source diffusion layer and a base diffusion layer are formed in regions of a semiconductor substrate located between a trench gate electrode and a trench emitter electrode that are spaced apart from each other. The trench emitter electrode, the base diffusion layer, and an insulating film have a recess that recede from a first main surface toward a second main surface. A shared contact member protrudes from the first main surface toward the second main surface in a manner contacting the recess. According to above structure of a semiconductor device, it is capable of efficiently discharging carriers to an emitter during turn-off.

In a general aspect, a semiconductor device can include a semiconductor region of a first conductivity type and a well region of a second conductivity type. The well region can be disposed in the semiconductor region. An interface between the well region and the semiconductor region can define a diode junction at a depth below an upper surface of the semiconductor region. The semiconductor device can further include at least one dielectric region disposed in the semiconductor region. A dielectric region of the at least one dielectric region can have an upper surface that is disposed in the well region at a depth in the semiconductor region that is above the depth of the diode junction; and a lower surface that is disposed in the semiconductor region at a depth in the semiconductor region that is the same depth as the diode junction or below the depth of the diode junction.

A transistor is produced by forming a first part of a first region of the transistor in a semiconductor substrate by implanting dopants through an opening in an isolating trench formed at an upper surface of the semiconductor substrate. A second region of the transistor in the opening by epitaxy.

A semiconductor device includes a semiconductor layer of a first conductivity type having a device forming region and an outside region, an impurity region of a second conductivity type formed in a surface layer portion of a first main surface in the device forming region, a field limiting region of a second conductivity type formed in the surface layer portion in the outside region and having a impurity concentration higher than that of the impurity region, and a well region of a second conductivity type formed in a region between the device forming region and the field limiting region in the surface layer portion in the outside region, having a bottom portion positioned at a second main surface side with respect to bottom portions of the impurity region and the field limiting region, and having a impurity concentration higher than that of the impurity region.

A method for manufacturing an electronic device includes locally implanting ionic species into a first region of a silicon nitride layer and into a first region of an electrically insulating layer located under the first region of the silicon nitride layer. A second region of the silicon nitride layer and a region of the electrically insulating layer located under the second region of the silicon nitride layer are protected from the implantation. The electrically insulating layer is disposed between a semi-conducting substrate and the silicon nitride layer. At least one trench is formed extending into the semi-conducting substrate through the silicon nitride layer and the electrically insulating layer. The trench separates the first region from the second region of the electrically insulating layer. The electrically insulating layer is selectively etched, and the etch rate of the electrically insulating layer in the first region is greater than the etch rate in the second region.

A method for manufacturing an electronic device includes locally implanting ionic species into a first region of a silicon nitride layer and into a first region of an electrically insulating layer located under the first region of the silicon nitride layer. A second region of the silicon nitride layer and a region of the electrically insulating layer located under the second region of the silicon nitride layer are protected from the implantation. The electrically insulating layer is disposed between a semi-conducting substrate and the silicon nitride layer. At least one trench is formed extending into the semi-conducting substrate through the silicon nitride layer and the electrically insulating layer. The trench separates the first region from the second region of the electrically insulating layer. The electrically insulating layer is selectively etched, and the etch rate of the electrically insulating layer in the first region is greater than the etch rate in the second region.

A method includes: in a semiconductor wafer having a first semiconductor layer and a second semiconductor layer adjoining the first semiconductor layer, forming a porous region extending from a front surface into the first semiconductor layer; and removing the porous region by an etching process, wherein a doping concentration of the second semiconductor layer is less than 10.sup.−2 times a doping concentration of the first semiconductor layer and/or a doping type of the second semiconductor layer is complementary to a doping type of the first semiconductor layer, wherein forming the porous region comprises bringing in contact a porosifying agent with the front surface of the first semiconductor layer and applying a voltage between the first semiconductor layer and a first electrode that is in contact with the porosifying agent, wherein applying the voltage comprises applying the voltage between the first electrode and an edge region of the first semiconductor layer.

A method of forming a semiconductor device is proposed. The method includes providing a semiconductor structure. The method further includes forming an auxiliary layer directly on a part of the semiconductor structure. Silicon and nitrogen are main components of the auxiliary layer. The method further includes forming a conductive material on the auxiliary layer. The conductive material incudes AlSiCu, AlSi or tungsten, and is electrically connected to the part of the semiconductor structure via the auxiliary layer.

A transistor is produced by forming a first part of a first region of the transistor in a semiconductor substrate by implanting dopants through an opening in an isolating trench formed at an upper surface of the semiconductor substrate. A second region of the transistor in the opening by epitaxy.

An insulated gate turn-off (IGTO) device, formed as a die, has a layered structure including a p+ layer (e.g., a substrate), an n− epi layer, a p-well, trenched insulated gate regions formed in the p-well, and n+ regions between the gate regions, so that vertical NPN and PNP transistors are formed. The device may be formed of a matrix of cells or may be interdigitated. To turn the device on, a positive voltage is applied to the gate, referenced to the cathode. The cells further contain a vertical p-channel MOSFET, for rapidly turning the device off. The p-channel MOSFET may be made a depletion mode device by implanting boron ions at an angle into the trenches to create a p-channel. This allows the IGTO device to be turned off with a zero gate voltage while in a latch-up condition, when the device is acting like a thyristor.