A method of producing a semiconductor device is disclosed in which, after proton implantation is performed, a hydrogen-induced donor is formed by a furnace annealing process to form an n-type field stop layer. A disorder generated in a proton passage region is reduced by a laser annealing process to form an n-type disorder reduction region. As such, the n-type field stop layer and the n-type disorder reduction region are formed by the proton implantation. Therefore, it is possible to provide a stable and inexpensive semiconductor device which has low conduction resistance and can improve electrical characteristics, such as a leakage current, and a method for producing the semiconductor device.

A semiconductor device includes a semiconductor region with a charge balance region on a junction blocking region, the junction blocking region having a lower doping concentration. The junction blocking region extends between a pair of trench structures in cross-sectional view. The trench structures are provided in the semiconductor region and include at least one insulated electrode. In some embodiments, the semiconductor device further includes a first doped region disposed between the pair of trench structures. The semiconductor device may further include one or more features configured to improve operating performance. The features include a localized doped region adjoining a lower surface of a first doped region and spaced apart from the trench structure, a notch disposed proximate to the lower surface of the first doped region, and/or the at least one insulated electrode configured to have a wide portion adjoining a narrow portion.

Systems, methods, and apparatus for use in biasing and driving high voltage semiconductor devices using only low voltage transistors are described. The apparatus and method are adapted to control multiple high voltage semiconductor devices to enable high voltage power control, such as power amplifiers, power management and conversion and other applications wherein a first voltage is large compared to the maximum voltage handling of the low voltage control transistors. A DC/DC power conversion implementation from high input voltage to low output voltage using a novel level shifter which uses only low voltage transistors is also provided. Also presented is a level shifter in which floating nodes and high voltage capacitive coupling and control enable the high voltage control with low voltage transistors.

A linear active cell region is formed from a plurality of divided active cell regions arranged apart from each other in a second direction (y direction). The linear hole collector cell region is formed from a plurality of divided hole collector cell regions arranged apart from each other in the second direction (y direction). A P-type floating region is formed in a semiconductor substrate between the linear active cell region and the linear hole collector cell region adjacent to each other in a first direction (x direction), between the divided active cell regions adjacent to each other in the second direction (y direction), and between the divided hole collector cell regions adjacent to each other in the second direction (y direction).

A semiconductor device with a high radiation tolerance is provided. A semiconductor device comprising a semiconductor substrate, a first body region and a second body region provided on a front surface side of the semiconductor substrate, a neck portion provided between the first body region and the second body region, a first source region formed within the first body region and a second source region formed within the second body region, a first gate electrode provided to face the first body region between the first source region and the neck portion, a second gate electrode provided to face the second body region between the second source region and the neck portion, and an insulating film continuously provided between the first gate electrode and the semiconductor substrate, between the second gate electrode and the semiconductor substrate, and on the front surface side of the neck portion, is provided.

Systems, methods, and apparatus for an improved body tie construction are described. The improved body tie construction is configured to have a lower resistance body tie exists when the transistor is off (Vg approximately 0 volts). When the transistor is on (Vg>Vt), the resistance to the body tie is much higher, reducing the loss of performance associated with presence of body tie. Space efficient Body tie constructions adapted for cascode configurations are also described.

Digital circuits are disclosed that may include multiple transistors having controllable current paths coupled between first and second logic nodes. One or more of the transistors may have a deeply depleted channel formed below its gate that includes a substantially undoped channel region formed over a relatively highly doped screen layer formed over a doped body region. Resulting reductions in threshold voltage variation may improve digital circuit performance. Logic circuit, static random access memory (SRAM) cell, and passgate embodiments are disclosed.

A method of manufacturing a semiconductor device includes forming electrode trenches in a semiconductor substrate between semiconductor mesas that separate the electrode trenches, the semiconductor mesas including portions of a drift layer of a first conductivity type and a body layer of a second, complementary conductivity type between a first surface of the semiconductor substrate and the drift layer, respectively. The method further includes forming isolated source zones of the first conductivity type in the semiconductor mesas, the source zones extending from the first surface into the body layer. The method also includes forming separation structures in the semiconductor mesas between neighboring source zones arranged along an extension direction of the semiconductor mesas, the separation structures forming partial or complete constrictions of the semiconductor mesa, respectively.

A power integrated circuit includes a double-diffused metal-oxide-semiconductor (LDMOS) transistor formed in a first portion of the semiconductor layer with a channel being formed in a first body region. The power integrated circuit includes a first deep diffusion region formed in the first deep well under the first body region and in electrical contact with the first body region and a second deep diffusion region formed in the first deep well under the drain drift region and in electrical contact with the first body region. The first deep diffusion region and the second deep diffusion region together form a reduced surface field (RESURF) structure in the LDMOS transistor.

A semiconductor device including a first N-type well and a second N-type well includes: a memory circuit to be coupled with first and second power source lines; and a first switch which electrically couples the first power source line with the second power source line and electrically decouples the first power source line from the second power source line. The memory circuit includes a memory array to be coupled with the second power source line, a peripheral circuit to be coupled with the first power source line, and a second switch which electrically couples the first power source line with the second power source line in the active mode and electrically decouples the first power source line from the second power source line in the standby mode. The first and second switches each include a first PMOS transistor arranged in the first N-type well.