Abstract: A semiconductor device includes a substrate; a first nanosheet transistor, which is located on the substrate, that has a first inter-channel spacing and that has a thin gate oxide layer; and a second nanosheet transistor, which is located on the substrate, that has a second inter-channel spacing that is greater than the first inter-channel spacing and that has a thick gate oxide layer that is thicker than the thin gate oxide layer of the first nanosheet transistor. The second nanosheet transistor comprises channel structures and a source/drain structure that wraps around the ends of the channel structures. In embodiments, there are inner spaces at ends of the gate stacks in the first transistor, but not at the ends of the gate stacks in the second transistor.

Abstract: A semiconductor device is provided and includes a first substrate including a first transistor; a laser reflection layer on the first transistor; and a second substrate on the laser reflection layer, the second substrate including a second transistor.

Abstract: Embodiments of present invention provide a semiconductor device. The semiconductor device includes a silicon (Si) substrate containing a set of short channel field-effect-transistors (FETs); a germanium (Ge) layer on top of the Si substrate containing a set of long channel p-type FETs (PFETs); and an oxide semiconductor layer on top of the Ge layer containing a set of long channel n-type FETs (NFETs), wherein the set of short channel FETs, long channel PFETs, and long channel NFETs are interconnected through a set of far-back-end-of-line (FBEOL) layers.

Abstract: A method of using special designed wiring level mask(s) to determine product transistor and circuit performance in a chip during the early portion of the product evaluation cycle saves weeks of time that would have been taken by the passage of the wafer through the fab. The method also saves cost during production by identifying wafers for rework at an early stage.

Abstract: A method for fabricating a dual gate structure, comprising providing a semiconductor substrate having a first device area and a second device area covered by a gate oxide layer and a polysilicon layer, forming a first hard mask over the polysilicon layer, said first hard mask being a material that is resistant to a first etching, but susceptible to a second etching forming a second hard mask over the first hard mask and the polysilicon layer, said second hard mask being a material that is resistant to a second etching, but susceptible to a first etching, patterning and etching said second hard mask with a first etch to form a gate pattern on a first device area, and patterning and etching said first hard mask with a second etch to transfer gate patterns on the first and second device areas.

Abstract: A method for fabricating a dual gate structure, comprising providing a semiconductor substrate having a first device area and a second device area covered by a gate oxide layer and a polysilicon layer, forming a first hard mask over the polysilicon layer, said first hard mask being a material that is resistant to a first etching, but susceptible to a second etching forming a second hard mask over the first hard mask and the polysilicon layer, said second hard mask being a material that is resistant to a second etching, but susceptible to a first etching, patterning and etching said second hard mask with a first etch to form a gate pattern on a first device area, and patterning and etching said first hard mask with a second etch to transfer gate patterns on the first and second device areas.

Abstract: A method of forming a resist layer of uniform thickness across a surface patterned with a varying density of high aspect ratio features. A selected material layer having an affinity to a resist coat to be applied over the selected material layer is applied to a wafer having a plurality of recesses before applying a resist coat. After the resist coat is applied over the selected material layer, the selected material diffuses partially into the resist coat to condition a portion of the resist coat to be insoluble in the presence of a developer which is applied after the resist coat. Those portions of the resist coat into which the selected material layer has not diffused then are removed by a developer leaving a uniform resist coat thickness across the wafer.

Abstract: A pair of transistors sharing a common electrodes e.g. a bitline in a DRAM array, has a self-aligned contact to the bitline in which the transistor gate stack has only a poly layer with a nitride cover; the aperture for the bitline contact is time-etched to penetrate only between the gates and not reach the silicon substrate; exposed nitride shoulders of the gate are etched to expose the poly; the remainder of the interlayer dielectric is removed by a selective etch; the exposed poly is re-oxidized to protect the gates; and the aperture bottom is cleaned; so that the thick gate stack of a DRAM is dispensed with in order to improve uniformity of line width across the chip beyond what the DRAM technique can deliver.