A semiconductor structure includes a bulk semiconductor substrate, an electrically insulating layer over the substrate, an active layer of semiconductor material over the electrically insulating layer and a transistor. The transistor includes an active region, a gate electrode region and an isolation junction region. The active region is provided in the active layer of semiconductor material and includes a source region, a channel region and a drain region. The gate electrode region is provided in the bulk semiconductor substrate and has a first type of doping. The isolation junction region is formed in the bulk semiconductor substrate and has a second type of doping opposite the first type of doping. The isolation junction region separates the gate electrode region from a portion of the bulk semiconductor substrate other than the gate electrode region that has the first type of doping.

Aspects of the present disclosure describe MOSFET devices that have snubber circuits. The snubber circuits comprise one or more resistors with a dynamically controllable resistance that is controlled by changes to a gate and/or drain potentials of the one or more MOSFET structures during switching events.

The present disclosure provides an integrated circuit. The integrated circuit includes a semiconductor substrate; and a passive polysilicon device disposed over the semiconductor substrate. The passive polysilicon device further includes a polysilicon feature; and a plurality of electrodes embedded in the polysilicon feature.

A semiconductor light detection element includes a plurality of avalanche photodiodes operating in Geiger mode and formed in a semiconductor substrate, quenching resistors connected in series to the respective avalanche photodiodes and arranged on a first principal surface side of the semiconductor substrate, and a plurality of through-hole electrodes electrically connected to the quenching resistors and formed so as to penetrate the semiconductor substrate from the first principal surface side to a second principal surface side. A mounting substrate includes a plurality of electrodes arranged corresponding to the respective through-hole electrodes on a third principal surface side. The through-hole electrodes and the electrodes are electrically connected through bump electrodes, and a side surface of the semiconductor substrate and a side surface of a glass substrate are flush with each other.

A chip part includes a substrate, an element formed on the substrate, and an electrode formed on the substrate. A recess and/or projection expressing information related to the element is formed at a peripheral edge portion of the substrate.

A method for manufacturing a semiconductor device comprises forming a first dummy gate layer on a substrate, forming a second dummy gate layer on the substrate adjacent the first dummy gate layer, wherein the second dummy gate layer comprises a material which is capable of being selectively etched with respect a material of the first dummy gate layer, and patterning each of the first and second dummy gate layers into a plurality of first dummy gate stacks and a plurality of second dummy gate stacks, respectively, wherein the first dummy gate stacks are each wider along a gate length direction than each of the second dummy gate stacks, wherein the patterning is performed using a reactive ion etch (RIE) process that results in different lateral trimming between the first and second dummy gate layers.

A semiconductor device structure including a resistor layer is provided. The semiconductor device structure includes a gate structure formed over the first region of the substrate and an inter-layer dielectric (ILD) layer formed adjacent to the gate structure. The semiconductor device structure further includes a resistor layer is formed over the ILD layer over the second region of the substrate, and the major structure of the resistor layer is amorphous.

A non-volatile memory device comprises a memory area including a memory cell, and a peripheral area including a circuit that drives the memory cell. The circuit includes a first resistance element. The first resistance element includes a first conductive layer extending in a first direction, a first insulating layer provided on the first conductive layer, and a second conductive layer that includes a portion provided on the first insulating layer and an end portion in contact with the first conductive layer.

In one example, a method of compensating resistance in an integrated circuit includes providing a four terminal resistor in a semiconductor substrate. The resistor includes a first resistor and a second resistor coupled in series, a first terminal at a first end of the resistor, a second terminal at a second end of the resistor, a test terminal at a node connecting the first resistor and the second resistor, and a tuning terminal. The first resistor has a first conductivity type and the second resistor has a second conductivity type opposite to the first conductivity type. The first resistor includes a first portion extending along a first direction and a second portion extending along a second direction perpendicular to the first direction. The method further includes computing a voltage to be applied at the tuning terminal to compensate the difference between the resistance of the first and the second resistors.

A metal-oxide-semiconductor field-effect transistor (MOSFET) with integrated passive structures and methods of manufacturing the same is disclosed. The method includes forming a stacked structure in an active region and at least one shallow trench isolation (STI) structure adjacent to the stacked structure. The method further includes forming a semiconductor layer directly in contact with the at least one STI structure and the stacked structure. The method further includes patterning the semiconductor layer and the stacked structure to form an active device in the active region and a passive structure of the semiconductor layer directly on the at least one STI structure.