Abstract: An emitter-switched thyristor structure includes a remote turn-off electrode for reducing turn-off time and increasing maximum controllable operating current. The switched thyristor structure further includes anode and cathode electrodes, with the remote electrode being connected to the cathode electrode. A multi-layer body of semiconductor material has a first surface, as well as regenerative and non-regenerative portions each operatively coupled between the anode and cathode electrodes. The regenerative portion includes adjacent first, second, third and fourth regions of alternating conductivity type arranged respectively in series. Electrical contacts exist between the remote electrode and the second region, as well as between the anode electrode and the fourth region. The thyristor is turned on by applying an enabling voltage to an insulated gate electrode disposed adjacent the first surface such that a conductive channel is created in the regenerative portion via modulation of the conductivity therein.

Abstract: An emitter switched thyristor with buried dielectric layer includes a contiguous P-N-P-N series of semiconductor regions between an anode contact and cathode contact. These regions correspond to an anode region of second conductivity type, a first base region of first conductivity type, a second base region of second conductivity type on the first base region, and a floating emitter region contacting the second base region and forming a P-N junction therewith. In addition, a field effect transistor is also provided between the cathode contact and the floating emitter for controlling turn-on and turn-off. An insulating region is also provided between the cathode region and the second base region and prevents the formation of a parasitic thyristor between the cathode contact and the anode contact. The insulating region preferably includes a buried dielectric layer selected from the group consisting of SiO.sub.2, Si.sub.3 N.sub.4, Al.sub.2 O.sub.3 and MgAl.sub.2 O.sub.4.

Abstract: An integrated multicelled thyristor includes a plurality of main thyristor cells and a plurality of edge thyristor cells. The main thyristor cells comprise source cells located in the center or innermost portion of an integrated thyristor and the edge cells are located at the periphery. In order to insure that all thyristor cells turn off uniformly, current exporting means is provided from the source cells to the edge cells to reduce current hole crowding in the peripheral cells. The anodes of all cells are electrically connected and the cathodes of all main cells are electrically connected. However, the cathodes of the edge cells are electrically connected to one or more source cells by the current exporting means. The unit cell of the multicelled device preferably comprises a BRT, but can comprise other well known thyristor structures where turn-off is limited by hole-current crowding.

Abstract: An emitter switched thyristor with base resistance control for preventing parasitic latch-up includes a P-N-P-N main thyristor with an N.sup.+ floating emitter for MOS-gated controlled turn-on and a lateral P-channel MOSFET for shunting hole current in a second base region to a P.sup.+ diverting region electrically connected to the cathode. The P-channel MOSFET is enabled by the application of a negative gate voltage to form a P-type inversion layer between the second base region and the P.sup.+ diverter region, thus reducing the resistance between the cathode and the second base region and raising the holding current of the emitter switched thyristor to above the operating current level. The formation of an alternative current path to the cathode has the further effect of reducing the forward bias across the base-emitter junction of an adjacent parasitic thyristor to thereby prevent the sustained regenerative action of the parasitic thyristor.

Abstract: An emitter switched thyristor without parasitic thyristor latch-up susceptibility includes a thyristor having an anode region, a first base region, a second base region in the first base region and an emitter region of first conductivity type in the second base region. An electrical connection is provided between the emitter region and the cathode contact by a field effect transistor in the first base region. The transistor is positioned adjacent the second base region and includes a source electrically connected to the emitter region by a metal strap on the surface of the substrate. The drain of the transistor is electrically connected to the cathode contact and has a conductivity type opposite the conductivity type of the first base region. Accordingly, the cathode contact and anode contact are not separated by a four layer parasitic thyristor. Parasitic latch-up operation is thereby eliminated.

Abstract: A method for forming an oxide-filled trench in silicon carbide includes the steps of amorphizing a portion of a monocrystalline silicon carbide substrate to thereby define an amorphous silicon carbide region in the substrate and then oxidizing the amorphous region to thereby form an oxide-filled trench in the substrate. Because of the enhanced rate of oxidation in the amorphous region as compared to the rate of oxidation of the surrounding monocrystalline silicon carbide regions at relatively low temperatures, the oxide-filled trench is generally defined by the lateral and vertical dimensions of the amorphous silicon carbide region. The amorphizing step includes the steps of masking an area on the face on the monocrystalline silicon carbide substrate to thereby expose a portion of the substrate wherein the amorphous region is to be formed and then directing ions to the face, such that the ions implant into the exposed portion of the substrate and create an amorphous silicon carbide region therein.

Abstract: A Schottky barrier rectifier includes regions of different Schottky barrier heights. Preferably, alternating regions of relatively high and relative low barrier heights are provided on a semiconductor substrate and are electrically connected in parallel to form a single Schottky barrier rectifier. The alternating regions may be provided by laterally spaced apart regions of a first metal on the semiconductor substrate and a layer of a second metal on the regions of the first metal and on the semiconductor substrate between the regions of first metal. Alternatively, a plurality of spaced apart barrier altering regions, such as a plurality of shallow implants, are formed in the semiconductor substrate, and a continuous metal layer is formed on the semiconductor substrate. In yet another embodiment, plurality of laterally spaced apart trenches are formed in the semiconductor substrate.

Abstract: A merged P-I-N/Schottky power rectifier includes trenches, and P-N junctions along the walls of the trenches and along the bottoms of the trenches. By forming the P-N junctions along the trench walls, the total area of the P-N junctions relative to the surface area of the device can be increased, to thereby improve the device's on-state characteristics without sacrificing the total area of the Schottky region. The trenches may be U or V shaped in transverse cross-section or of other transverse cross-sectional shape, and the trenches may be polygonal or circular in top view.

Abstract: A base resistance controlled thyristor with integrated single-polarity gate control includes a thyristor having an anode region, a first base region, a second base region on the first base region and a cathode region contacting the second base region and defining a P-N junction therewith. For providing gated turn-off control, a depletion-mode field effect transistor is provided on the second base region and is separated therefrom by an insulating region. In particular, an insulating region, such as a buried dielectric layer, is provided on the second base region and the depletion-mode field effect transistor is formed thereon. The depletion-mode field effect transistor is electrically connected between the cathode contact and the second base region and provides a direct electrical connection therebetween in response to a turn-off bias signal which is preferably a zero or near zero bias.

Abstract: A silicon carbide power MOSFET device includes a first silicon carbide layer, epitaxially formed on the silicon carbide substrate of opposite conductivity type. A second silicon carbide layer of the same conductivity type as the substrate is formed on the first silicon carbide layer. A power field effect transistor is formed in the device region of the substrate and in the first and second silicon carbide layers thereover. At least one termination trench is formed in the termination region of the silicon carbide substrate, extending through the first and second silicon carbide layers thereover. The termination trench defines one or more isolated mesas in the termination region which act as floating field rings. The termination trenches are preferably insulator lined and filled with conductive material to form floating field plates. The outermost trench may be a deep trench which extends through the first and second silicon carbide layers and through the drift region of the silicon carbide substrate.

Abstract: A base resistance controlled thyristor with single-polarity and dual-polarity turn-on and turn-off control includes a turn-off device provided between the second base region and the cathode of a thyristor. Controlled turn-off is provided by either a near-zero positive bias or a negative bias being applied to the turn-off device. In the preferred embodiment, the turn-off device is a P-channel depletion-mode MOSFET in the surface of a semiconductor substrate. Accordingly, an accumulation-layer channel can be formed between the second base region and the cathode in response to a negative bias. Alternatively, if single-polarity control is desired, the P-type channel is provided to turn-off the device in response to a near-zero positive bias. In either type of operation, however, advantages are obtained over conventional turn-off devices wherein inversion-layer channels are used.

Abstract: A semiconductor power switching device comprises a multicellular FET structure with a Schottky barrier diode structure interspersed therewith with at least some of the FET cells being free of Schottky barrier portions. The ratio of Schottky barrier contact area to FET cell area in the overall device may be adjusted to tailor the device for operation at specific current densities.

Abstract: An integrated circuit power device is disclosed having a large number of individual devices formed in an integrated circuit. Disabling devices are provided in the integrated circuit, a respective one of which is electrically connected to an associated one or more of the individual devices. Each of the disabling devices is responsive to a defect in the associated one or more individual devices, such as a short circuit, for automatically disabling the associated one or more individual devices. An operable integrated circuit power device is obtained, notwithstanding a defective one or more of the individual devices. Testing of individual devices, or customized mask generation is not necessary. In a preferred embodiment, the disabling device is a fusible link formed of a low melting point conductor.

Abstract: A multi-cellular power field effect semiconductor device includes a high conductivity layer of metal or a metal silicide disposed in intimate contact with the source region of the device. This high conductivity layer is self-aligned with respect to the aperture in the gate electrode through which the source region is diffused. The presence of this high conductivity layer allows a substantially smaller contact window to be employed for making contact between the final metallization and the source region. As a consequence, the aperture in the gate electrode and the cell size of the device can both be substantially reduced. The device has substantially improved operating characteristics. A method of producing the device is also described.

Abstract: A UMOS IGBT has a source electrode ohmic contact area which is at least 40% base region and preferably at least 50% base region in order to provide a high latching current and a large safe operating area.

Abstract: A field controlled diode is provided with an insulated gate electrode for controlling the conductivity of the diode. The diode is turned off by applying a gate bias voltage which pinches off the drift region of the device to block current flow in the anode/cathode diode path. The turn-off characteristics of the device are enhanced by including transistor portions in the structure in which the drift region is not pinched off during turn-off to facilitate extraction of stored charge from the diode structure.

Abstract: A multi-cellular power field effect semiconductor device includes a tungsten silicide/polysilicon/oxide gate electrode stack with low sheet resistance. Preferably, a layer of tungsten is also disposed in intimate contact with the source region of the device. This tunsten layer is self-aligned with respect to the aperture in the gate electrode through which the source region is diffused. The presence of this tungsten layer greatly reduces the resulting ohmic contact resistance to the region. If desired, a tunsten layer can also be disposed in contact with the drain region of the device, again, to lower ohmic contact resistance. The device has substantially improved operating characteristics. Novel processes for producing the device are also described.

Abstract: A semiconductor power rectifier attains low forward voltage drop, low reverse leakage current and improved switching speed by utilizing Schottky contact regions in a p-i-n rectifier along with other means for reducing the required forward bias voltage. In a preferred embodiment, the other means for reducing the required forward bias voltage includes a respective trench between each respective pair of successively spaced current interruption means.

Abstract: In a depletion mode thyristor of the type including a regenerative portion and a non-regenerative portion, the turn-off time for the thyristor is substantially reduced without producing a corresponding increase in the on-resistance of the device by providing a region of relatively low carrier lifetime in the non-regenerative portion of the device in the layer or layers in which charge storage limits the turn-off time for the device. Turn-off of the thyristor is accomplished by pinching off the regenerative portion, thereby diverting current into the low carrier lifetime non-regenerative portion.

Abstract: A MOS-pilot structure for an IGT device consisting of a multiplicity of IGT cells interconnected in a lattice network includes a plurality of pilot emitter electrodes each in electrical contact with only at least one pilot emitter region of a first plurality of the multiplicity of IGT cells and electrically isolated from a common cathode electrode of the multiplicity of IGT cells. The plurality of pilot emitter electrodes are each electrically connected to a contact metal strip deposited on the substrate surface and spaced therefrom by a layer of insulation. The contact metal strip is connected to ground potential through a sense resistor for producing a sense voltage responsive only to the channel currents flowing through the at least one pilot emitter regions; therefore, a MOS pilot structure that utilizes only the MOS channel current to produce the sense voltage to cause turn-off of the IGT device at a large total current is disclosed.