A reverse-conducting insulated gate bipolar transistor (IGBT) includes a first conductivity type boundary layer of a first conductivity type and a second conductivity type boundary layer of a second conductivity type disposed in a boundary region located between an IGBT region and a diode region. The first conductivity type boundary layer is disposed below a drift layer, and is in contact with a lower electrode. The second conductivity type boundary layer is disposed between the first conductivity type boundary layer and the drift layer.

A semiconductor substrate of a reverse conducting IGBT has a first conductivity type buffer layer disposed between a collector layer and a drift layer. The buffer layer has a first buffer layer provided in the IGBT region and a second buffer layer provided in the boundary region. The peak concentration of the first conductivity type impurity in the second buffer layer is higher than that in the first buffer layer.

A semiconductor structure is disclosed. The semiconductor structure includes: a semiconductor substrate having a front surface and a back surface facing opposite to the front surface; a filling material extending from the front surface into the semiconductor substrate without penetrating through the semiconductor substrate, the filling material including an upper portion and a lower portion, the upper portion being in contact with the semiconductor substrate; and an epitaxial layer lined between the lower portion of the filling material and the semiconductor substrate. An associated manufacturing method is also disclosed.

A method of manufacturing a transfer die for use in a transfer print process. The manufactured transfer die comprises a semiconductor device suitable for bonding to a silicon-on-insulator wafer. The method comprises the steps of providing a non-conductive isolation region in a semiconductor stack, the semiconductor stack comprising a sacrificial layer above a substrate; and etching an isolation trench into the semiconductor stack from an upper surface thereof, such that the isolation trench extends only to a region of the semiconductor stack above the sacrificial layer. The isolation trench and the non-conductive isolation region together separate a bond pad from a waveguide region in the optoelectronic device.

The present disclosure provides one embodiment of a method of forming an integrated circuit structure. The method includes forming a shallow trench isolation (STI) structure in a semiconductor substrate of a first semiconductor material, thereby defining a plurality of fin-type active regions separated from each other by the STI structure; forming gate stacks on the fin-type active regions; forming an inter-layer dielectric (ILD) layer filling in gaps between the gate stacks; patterning the ILD layer to form a trench between adjacent two of the gate stacks; depositing a first dielectric material layer that is conformal in the trench; filling the trench with a second dielectric material layer; patterning the second dielectric material layer to form a contact opening; and filling a conductive material in the contact opening to form a contact feature.

A method for fabricating a semiconductor device includes receiving a silicon substrate having an isolation feature disposed on the substrate and a well adjacent the isolation feature, wherein the well includes a first dopant. The method also includes etching a recess to remove a portion of the well and epitaxially growing a silicon layer (EPI layer) in the recess to form a channel, wherein the channel includes a second dopant. The method also includes forming a barrier layer between the well and the EPI layer, the barrier layer including at least one of either silicon carbon or silicon oxide. The barrier layer can be formed either before or after the channel. The method further includes forming a gate electrode disposed over the channel and forming a source and drain in the well.

Methods of forming high aspect ratio openings. The method comprises removing a portion of a dielectric material at a temperature less than about 0 C. to form at least one opening in the dielectric material. The at least one opening comprises an aspect ratio of greater than about 30:1. A protective material is formed in the at least one opening and on sidewalls of the dielectric material at a temperature less than about 0 C. Methods of forming high aspect ratio features are also disclosed, as are semiconductor devices.

A method of fabricating a semiconductor device includes forming a first layer which has a first surface, does not contain an acid, and contains a metal material. The method includes forming, on the first layer, a second layer which includes a trench exposing the first surface. The second layer has a second surface intersecting the first surface within the trench, and contains an acid and an organic material. The method further including a first precursor containing an alkoxy group and silicon; and forming a third layer containing silicon oxide on the second surface within the trench. The third layer is in contact with a portion of the first surface within the trench.

A manufacturing method of a gate structure includes the following steps. A semiconductor substrate is provided. An isolation structure is formed in the semiconductor substrate and surrounds an active region in the semiconductor substrate. A gate pattern is formed on the active region and the isolation structure. The gate pattern includes a first gate structure and a first capping layer disposed on the first gate structure. A part of the first capping layer located above an interface between the active region and the isolation structure is removed for exposing a part of the first gate structure located above the interface between the active region and the isolation structure. A removing process is performed for reducing a thickness of the part of the first gate structure located above the interface between the active region and the isolation structure.

The present application provides a method of fabricating a conductive feature. The method of fabricating the conductive feature includes steps of depositing an insulative layer on a substrate, forming a trench in the insulative layer, performing a cyclic process comprising a sequence of a deposition step and a removal step to deposit a conductive material in the trench until the deposition step has been performed is equal to a first preset number of times and a number of the times the removal step has been performed is equal to a second preset number of times, and filling the trench with the conductive material after the cyclic process.