摘要:
A dynamic storage element has an electrically insulating layer carried on a substrate of semiconductor material. A conductor path, provided with a terminal, is arranged on the electrically insulating layer, and first and second zones, doped oppositely to the substrate, are provided on the surface of the substrate. The zones are spaced from one another. In that region of the substrate between the zones the substrate is more highly doped with dopants of the same type as those contained in the substrate and the conductor path extends above the highly doped region.
摘要:
A semiconductor element has a semiconductor body of a first conductivity type. The semiconductor body has a zone of a second conductivity type embedded. Further regions of the second conductivity type surround the zone of the second conductivity type like a well. The further regions are interrupted in at least one location by a channel that is formed by the semiconductor body. The further regions are doped with a doping concentration that is high enough so that the further regions are not completely depleted of charge carriers when the semiconductor element is revere-biased.
摘要:
The invention relates to a method for fabricating a drift zone of a vertical semiconductor component and to a vertical semiconductor component having the following features: a semiconductor body (100) having a first side (101) and a second side (102), a drift zone (30) of a first conduction type which is arranged in the region between the first and the second sides (101, 102) and is formed for the purpose of taking up a reverse voltage, a field electrode arrangement arranged in the drift zone (30) and having at least one electrically conducted field electrode (40; 40A-40E; 90A-90J) arranged in a manner insulated from the semiconductor body (100), an electrical potential of the at least one field electrode (40; 40A-40E; 90A-90J) varying in the vertical direction of the semiconductor body (100) at least when a reverse voltage is applied.
摘要:
A temperature-protected semiconductor circuit configuration that has an integrated switching unit. The switching unit is formed of a semiconductor switch, a first integrated temperature sensor for driving the semiconductor switch when an over-temperature is reached, first and second connecting terminals for connecting a load, and a control terminal for applying a drive signal for the semiconductor switch. A second temperature sensor is connected in a heat-conducting manner to the switching unit which exhibits at least one output terminal for providing a temperature-dependent temperature signal.
摘要:
A junction field-effect transistor containing a semiconductor region with an inner region is described. In addition, a first and a second connecting region, respectively, are disposed within the semiconductor region. The first connecting region has the same conductivity type as the inner region, but in a higher doping concentration. The second connecting region has the opposite conductivity type to that of the inner region. This reduces the forward resistance while at the same time maintaining a high reverse voltage strength.
摘要:
The invention relates to a vertical power MOSFET having additional column-like zones (11, 12) which are arranged in an inner zone (1) and have the same and the opposite conductivity type as/to the inner zone (1). The charge carrier life is reduced in the additional zones (12), which are of the same conductivity type as the inner zone (1), and the inner zone (1) is dimensioned such that the space charge zone does not reach the junction between the inner zone and a drain zone.
摘要:
A lateral silicon carbide junction field effect transistor has p-conductive and n-conductive silicon carbide layers. The layers are provided in pairs in lateral direction in a silicon carbide body. Trenches for a source, a drain and a gate extend from a principal surface of the silicon carbide body and penetrate the layers. The source and drain trenches are filled with silicon carbide of one conductivity type, whereas the trench for the gate is filled with silicon carbide of a conductivity type that is different from the source and the drain.
摘要:
A lateral high-voltage transistor has a semiconductor body made of a lightly doped semiconductor substrate of a first conductivity type and an epitaxial layer of a second conductivity type. The epitaxial layer is provided on the semiconductor substrate. The lateral high-voltage transistor has a drain electrode, a source electrode, a gate electrode and a semiconductor zone of the first conductivity type which is provided under the gate electrode and is embedded in the epitaxial layer. Between the source electrode and the drain electrode trenches are provided in lines and rows in the semiconductor layer. The walls of the trenches are highly doped with dopants of the first conductivity type.
摘要:
The semiconductor component, such as a Schottky diode with a low leakage current, has a metal-semiconductor junction between a first metal electrode and the semiconductor. The semiconductor, which is of a first conductivity type, has a defined drift path and a plurality of supplementary zones of a second conductivity type extending from the semiconductor surface into the drift path. A number of foreign atoms in the supplementary zones is substantially equal to a number of foreign atoms in intermediate zones surrounding the supplementary zones and the number of foreign atoms does not exceed a number corresponding to a breakdown charge of the semiconductor.
摘要:
The circuit configuration captures the load current of a field effect-controllable power semiconductor component. The drain and gate terminals of a further field effect-controllable semiconductor component are connected to the drain and gate terminals, respectively, of the first semiconductor component. A fraction of the load current flows through the further semiconductor component. The load current of the further semiconductor component is set as a function of the drain-to-source voltage of the two semiconductor components. The load current flowing through the further semiconductor component is compared with a reference current and an output signal is generated if the load current falls below a set value.