A semiconductor device of an embodiment includes a p-type SiC impurity region containing a p-type impurity and an n-type impurity. Where the p-type impurity is an element A and the n-type impurity is an element D, the element A and the element D form a combination of Al (aluminum), Ga (gallium), or In (indium) and N (nitrogen), and/or a combination of B (boron) and P (phosphorus). The ratio of the concentration of the element D to the concentration of the element A in the above combination is higher than 0.33 but lower than 0.995, and the concentration of the element A forming part of the above combination is not lower than 110.sup.18 cm.sup.3 and not higher than 110.sup.22 cm.sup.3.

A semiconductor device comprising a source region being electrically connected to a first load terminal (E) of the semiconductor device and a drift region comprising a first semiconductor material (M1) having a first band gap, the drift region having dopants of a first conductivity type and being configured to carry at least a part of a load current between the first load terminal (E) and a second load terminal (C) of the semiconductor device, is presented. The semiconductor device further comprises a semiconductor body region having dopants of a second conductivity type complementary to the first conductivity type and being electrically connected to the first load terminal (E), a transition between the semiconductor body region and the drift region forming a pn-junction, wherein the pn-junction is configured to block a voltage applied between the first load terminal (E) and the second load terminal (C).The semiconductor body region isolates the source region from the drift region and includes a reduced band gap zone comprising a second semiconductor material (M2) having a second band gap that is smaller than the first band gap, wherein the reduced band gap zone is arranged in the semiconductor body region such that the reduced band gap zone and the source region exhibit, in a cross-section along a vertical direction (Z), at least one of a common lateral extension range (LR) along a first lateral direction (X) and a common vertical extension range (VR) along the vertical direction (Z).

The invention provides a semiconductor device. The semiconductor device includes a buried oxide layer disposed on a substrate. A semiconductor layer having a first conduction type is disposed on the buried oxide layer. A first well doped region having a second conduction type is disposed in the semiconductor layer. A cathode doped region having the second conduction type is disposed in the first well doped region. A first anode doped region having the first conduction type is disposed in the first well doped region, separated from the cathode doped region. A first distance from a bottom boundary of the first anode doped region to a top surface of the semiconductor layer is greater than a second distance from the bottom boundary to an interface between the semiconductor layer and the buried oxide layer.

Data stored in a plurality of charge storage elements in a three-dimensional memory device can be read with high speed by measuring a majority charge carrier current passing through a vertical semiconductor channel. A memory film is provided in a memory opening extending through an alternating stack of insulating layers and electrically conductive layers. A set of doped semiconductor material regions having a doping of a first conductivity type can collectively extend continuously from underneath a top surface of a substrate through the memory film to a level of a topmost layer of the alternating stack. A well contact via structure can contact a doped contact region, which is an element of the set of doped semiconductor material regions. A p-n junction is provided within each memory opening between the doped vertical semiconductor channel and an upper doped semiconductor region having a doping of a second conductivity type.

A semiconductor device includes: an N.sup. drift layer of a first conductivity type formed in the semiconductor substrate; a P base layer formed on the N.sup. drift layer; and an N buffer layer of the first conductivity type formed under the N.sup. drift layer and higher in peak impurity concentration than the N.sup. drift layer. The N buffer layer includes: a first buffer layer in which a trap level derived from lattice defect is not detected by a photoluminescence method; and a second buffer layer provided between the first buffer layer and the N.sup. drift layer and in which two types of trap levels derived from lattice defect are detected by the photoluminescence method.

In a general aspect, a method can include forming well region of one conductivity type in a semiconductor region of another conductivity type 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 method can further include forming at least one dielectric region 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 diode is formed in an active region. The diode includes a P-type component embedded in a first portion of the active region, an N-type component embedded in a second portion of the active region, and an undoped component disposed between the P-type component and the N-type component. An interconnect structure is formed over a first side of the diode. Different portions of the interconnect structure are electrically coupled to the P-type component and the N-type component, respectively. One or more openings are etched through a dielectric structure disposed over a second side of the diode opposite the first side. A dopant material is implanted into the active region through the one or more openings. The one or more openings are filled with a conductive material.

A diode includes a P-type region, an N-type region, and an undoped intrinsic region. A first conductive contact and a second conductive contact are each disposed over a first side of the diode. The first conductive contact is electrically coupled to the P-type region from the first side. The second conductive contact is electrically coupled to the N-type region from the first side. A first conductive via and a second conductive via are each disposed over a second side of the diode. The second side is different from the first side. The first conductive via is electrically coupled to the P-type region from the second side. The second conductive via is electrically coupled to the N-type region from the second side. The first conductive contact is electrically coupled to the first conductive via. The second conductive contact is electrically coupled to the second conductive via.

High frequency power diode including a semiconductor wafer having first and second main sides, a first layer of a first conductivity type formed on the first main side, a second layer of a second conductivity type formed on the second main side and a third layer of the second conductivity type formed between the first layer and the second layer. The first layer has a dopant concentration decreasing from 10.sup.19 cm.sup.3 or more adjacent to the first main side of the wafer to 1.5.Math.10.sup.15 cm.sup.3 or less at an interface of the first layer with the third layer. The second layer has a dopant concentration decreasing from 10.sup.19 cm.sup.3 or more adjacent to the second main side of the wafer to 1.5.Math.10.sup.15 cm.sup.3 at an interface of the second layer with the third layer and the third layer has a dopant concentration of 1.5.Math.10.sup.15 cm.sup.3 or less.

An ESD (electrostatic discharge) protection device includes a first III-nitride p-i-n diode and a second III-nitride p-i-n diode connected to the first III-nitride p-i-n diode in an antiparallel arrangement configured to provide voltage clamping at 5V or less under forward bias of either the first or second III-nitride p-i-n diode for transient current in both forward and reverse directions. A corresponding method of manufacturing the ESD protection device is also provided.