A method to form a 3D integrated circuit, the method including: providing a first wafer including a first crystalline substrate, a plurality of first transistors, and first copper interconnecting layers, where the first copper interconnecting layers at least interconnect the plurality of first transistors; providing a second wafer including a second crystalline substrate, a plurality of second transistors, and second copper interconnecting layers, where the second copper interconnecting layers at least interconnect the plurality of second transistors; and then performing a face-to-face bonding of the second wafer on top of the first wafer, where the face-to-face bonding includes copper to copper bonding; and thinning the second crystalline substrate to a thickness of less than 5 micro-meters.

In some embodiments, the present disclosure relates to a semiconductor device including a semiconductor region over a bulk oxide, which is over a semiconductor substrate. Above the bulk oxide is a lower source region that is laterally spaced from a lower drain region by a lower portion of the semiconductor region. An upper source region is laterally spaced from an upper drain region by an upper portion of the semiconductor region and is vertically spaced from the lower source region and the lower drain region. The upper source region is coupled to the lower source region, and the upper drain region is coupled to the lower drain region. A gate electrode, coupled to the semiconductor substrate and over a gate oxide, is above the upper portion of the semiconductor region. The lower and upper portions of the semiconductor region respectively include a first channel region and a second channel region.

An electronic circuit is disclosed. The electronic circuit includes: a first transistor device integrated in an inner region of a first semiconductor body; a level shifter integrated in a level shifter region of the first semiconductor body, the level shifter region located in an edge region surrounding the inner region of the semiconductor body; and a drive circuit integrated in a drive circuit region in the edge region of the first semiconductor body, the drive circuit configured to receive a first input signal from a first input and drive the first transistor device based on the first input signal, the drive circuit region arranged closer to the inner region than the level shifter region.

A semiconductor package includes a leadframe having an electrically conductive paddle, electrically conductive perimeter package leads, a first electrically conductive clip electrically connected to a first set of the package leads, and a second electrically conductive clip electrically connected to a second set of the package leads. The semiconductor package includes a single semiconductor die. The die includes a front-side active layer having an integrated power structure of two or more transistors. The die includes a backside portion having a backside contact electrically coupled to at least one of the two or more transistors and to the paddle. One or more first front-side contacts of the die are electrically coupled to at least one of the transistors and to the first clip, and one or more second front-side contacts of the die are electrically coupled to at least one of the transistors and to the second clip.

A semiconductor structure that includes at least one lateral diffusion field effect transistor is described. The structure includes a source contact and a gate shield that enables the line width of an ohmic region that electrically connects the source/body region to the gate shield to be smaller than the minimum contact feature size. The gate shield defines a bottom recess for forming a narrower bottom portion of the source contact, and a section that flares outward with distance from the ohmic region to extend above and laterally beyond the ohmic region. By providing a wider area for the source contact, the flared portion of the gate shield allows the portion of the gate shield that contacts the ohmic region to be narrower than the minimum contact feature size. As a result, the cell pitch of the lateral diffusion field effect transistor can be reduced.

A structure of a protruding gate transistor is disclosed. The protruding gate transistor comprising a substrate, a source region, a drain region, a channel extension anchor, a channel layer, and gate structure. The gate structure comprising a gate insulator layer, and a gate conductor layer. The channel layer is formed to be protruding from the substrate to extend the length of the channel of the protruding gate transistor and alleviate from channel length modulation.

A device includes an active semiconductor layer on top of and in contact with an insulating layer which overlies a semiconductor substrate. A transistor for the device includes a source region, a drain region, and a body region arranged in the active semiconductor layer. The body region of the transistor is electrically coupled to the semiconductor substrate using a conductive via that crosses through the insulating layer.

A semiconductor package includes a leadframe having an electrically conductive paddle, electrically conductive perimeter package leads, a first electrically conductive clip electrically connected to a first set of the package leads, and a second electrically conductive clip electrically connected to a second set of the package leads. The semiconductor package includes a single semiconductor die. The die includes a front-side active layer having an integrated power structure of two or more transistors. The die includes a backside portion having a backside contact electrically coupled to at least one of the two or more transistors and to the paddle. One or more first front-side contacts of the die are electrically coupled to at least one of the transistors and to the first clip, and one or more second front-side contacts of the die are electrically coupled to at least one of the transistors and to the second clip.

An electronic circuit is disclosed. The electronic circuit includes: a first transistor device integrated in an inner region of a first semiconductor body; a level shifter integrated in a level shifter region of the first semiconductor body, the level shifter region located in an edge region surrounding the inner region of the semiconductor body; and a drive circuit integrated in a drive circuit region in the edge region of the first semiconductor body, the drive circuit configured to receive a first input signal from a first input and drive the first transistor device based on the first input the drive circuit region arranged closer to the inner region than the level shifter region.

A method for making a semiconductor device may include forming a superlattice on a semiconductor substrate and including a plurality of stacked groups of layers. Each group of layers of the superlattice may include a plurality of stacked base semiconductor monolayers defining a base semiconductor portion and at least one non-semiconductor monolayer constrained within a crystal lattice of adjacent base semiconductor portions. A first at least one non-semiconductor monolayer may be constrained within the crystal lattice of a first pair of adjacent base semiconductor portions and comprise a first non-semiconductor material, and a second at least one non-semiconductor monolayer may be constrained within the crystal lattice of a second pair of adjacent base semiconductor portions and comprise a second non-semiconductor material different than the first non-semiconductor material.