摘要:
A field controlled semiconductor device of SiC has a drain, a highly doped substrate layer on top of the drain and a low doped n-type drift layer on top of the substrate layer. A p-type base layer is located on the drift layer and a vertical trench extends through the base layer. In the trench an n-type channel region extends vertically along a wall of the trench and connects a source region layer to the drift layer. A gate electrode is arranged in the trench to be on the opposite side of the channel region with respect to the base layer.
摘要:
A transistor of SiC having a drain and a highly doped substrate layer is formed on the drain. A highly n type buffer layer may optionally be formed on the substrate layer. A low doped n-type drift layer, a p-type base layer, a high doped n-type source region layer and a source are formed on the substrate layer. An insulating layer with a gate electrode is arranged on top of the base layer and extends substantially laterally from at least the source region layer to a n-type layer. When a voltage is applied to the gate electrode, a conducting inversion channel is formed extending substantially laterally in the base layer at an interface of the p-type base layer and the insulating layer. The p-type base layer is low doped in a region next to the interface to the insulating layer at which the inversion channel is formed and highly doped in a region thereunder next to the drift layer.
摘要:
A semiconductor device of SiC is adapted to hold high voltages in the blocking state thereof. The device comprises two parts (1, 2) each comprising one or more semiconductor layers of SiC and connected in series between two opposite terminals of the device, namely a sub-semiconductor device (1) able to withstand only low voltages in the blocking state thereof and a voltage-limiting part (2) able to withstand high voltages in the blocking state of the device and adapted to protect said sub-semiconductor device by taking a major part of the voltage over the device in the blocking state thereof.
摘要:
A field controlled semiconductor device of SiC comprises superimposed in the order mentioned at least a drain (12), a highly doped substrate layer (1) and a low doped n-type drift layer (2). It has also a highly doped n-type source region layer (6) and a source (11) connected thereto. A doped channel region layer (4) connects the source region layer to the drift layer, and a current is intended to flow therethrough when the device is in an on-state. The device has also a gate electrode (9). The channel region layer has a substantially lateral extension and is formed by a low doped n-type layer (4). The gate electrode (9) is arranged to influence the channel region layer from above for giving a conducting channel (17) created therein from the source region layer to the drift layer a substantially lateral extension.
摘要:
An IGBT comprises a drain, a highly doped p-type substrate layer, a highly doped n-type buffer layer, a drift layer, a p-type base layer, a highly doped n-type source region layer and a source electrode. A trench is etched in the base layer and an insulating layer with a gate electrode thereon is arranged on the base layer from the source region layer to the drift layer for the creation of a conducting inversion channel there. A contact portion is provided vertically separated from the source region layer and has the source electrode applied thereon for collecting holes injected from the substrate layer to the drift layer at a vertical distance from the source region layer.
摘要:
An insulated gate bipolar transistor comprises a drain which supports a highly doped p-type substrate layer; a low doped n-type drift layer supported over the substrate layer; a base layer supported over the drift layer including a trench extending into the base layer, and supporting an insulated gate on an upper surface thereof separated from the trench by a highly doped n-type source region, the trench having a highly doped p-type layer at the bottom thereof vertically separated from the source region; and a source layer disposed over the n-type source region and extending into the trench covering the highly doped p-type layer in the trench bottom, wherein an applied voltage to the gate forms a conducting inversion channel in the base layer for electron transport from the source region to the drain, and the highly doped p-type layer in the bottom of the trench collects holes injected from the substrate layer into the drift layer thereby improving latch up immunity for the transistor.
摘要:
A unipolar semiconductor device having a drift layer (3) doped according to a first conductivity type forming a conducting path and regions (7, 8) doped according to a second conductivity type and arranged next to the drift layer, has the drift layer and the regions of a semiconductor material having an ionization energy Ei of dopants of the second conductivity type therein exceeding 0.5 eV and/or a solubility of the dopants of the second conductivity type therein being less than 1018 cm−3.
摘要:
A unipolar semiconductor device having a drift layer (3) doped according to a first conductivity type forming a conducting path and regions (7, 8) doped according to a second conductivity type and arranged next to the drift layer, has the drift layer and the regions of a semiconductor material having an ionization energy Ei of dopants of the second conductivity type therein exceeding 0.5 eV and/or a solubility of the dopants of the second conductivity type therein being less than 1018 cm−3.
摘要:
A semiconductor device comprises at least one first semiconductor layer (1-4) and a second layer (8) applied on at least a surface portion of the first layer for protecting the device. The protecting layer is of a second material having a larger energy gap between the valence band and the conduction band than a first material forming said first layer. The second material has at least in one portion of said protecting layer a nano-crystalline and amorphous structure by being composed of crystalline gains with a size less than 100 nm and a resistivity at room temperature exceeding 1×1010 &OHgr;cm.
摘要:
In a method for producing a channel region layer in a SiC-layer for providing a voltage-controlled semiconductor device a layer of silicon being one of a) polycrystalline and b) amorphous is applied on top of the SiC-layer, an aperture is etched in the silicon layer extending to the SiC-layer, a surface layer of a certain thickness of the silicon layer is oxidized, and the lateral extension of the channel region layer is determined by removing the oxidized layer and carrying out a further implantation into the area exposed by the so formed enlarged aperture.