A method comprises forming a gate structure between gate spacers; etching back the gate structure to fall below top ends of the gate spacers; forming a gate dielectric cap over the etched back gate structure; performing an ion implantation process to form a doped region in the gate dielectric cap; depositing a contact etch stop layer over the gate dielectric cap and an ILD layer over the contact etch stop layer; performing a first etching process to form a gate contact opening extending through the ILD layer and terminating prior to reaching the doped region of the gate dielectric cap; performing a second etching process to deepen the gate contact opening, wherein the second etching process etches the doped region of the gate dielectric cap at a slower etch rate than etching the contact etch stop layer; and forming a gate contact in the deepened gate contact opening.

A semiconductor device includes: a sidewall insulating film; a gate electrode; source and drain regions; a first stress film; and a second stress film.

The present disclosure provides a method for preparing a semiconductor device. The method includes forming a sacrificial source/drain structure over a first carrier substrate; forming a redistribution structure over the sacrificial source/drain structure;

attaching the redistribution structure to a second carrier substrate; removing the first carrier substrate after the redistribution structure is attached to the second carrier substrate; replacing the sacrificial source/drain structure with a first source/drain structure; forming a backside contact over and electrically connected to the first source/drain structure; and forming an interconnect part over the backside contact.

A semiconductor device with densified dielectric structures and a method of fabricating the same are disclosed. The method includes forming a fin structure, forming an isolation structure adjacent to the fin structure, forming a source/drain (S/D) region on the fin structure, depositing a flowable dielectric layer on the isolation structure, converting the flowable dielectric layer into a non-flowable dielectric layer, performing a densification process on the non-flowable dielectric layer, and repeating the depositing, converting, and performing to form a stack of densified dielectric layers surrounding the S/D region.

A method for manufacturing a semiconductor device includes: forming an isolating layer on a surface of a substrate; forming a groove on the isolating layer, where the groove penetrates the isolating layer; forming a protection layer in the groove and on the isolating layer; forming a dielectric layer on the protection layer; and forming a contact hole, where the contact hole penetrates the protection layer and the dielectric layer to the surface of the substrate, respectively. The method for manufacturing the semiconductor device according to the present invention can be used not only in chemical vapor deposition but also in a process of a metal wire of a short-circuit in physical vapor deposition.

The present disclosure provides a method for fabricating a semiconductor structure, including forming a dielectric layer over a first region and a second region of a substrate, wherein the second region is adjacent to the first region, increasing a thickness of the dielectric layer in the first region, including forming an oxygen capturing layer over the dielectric layer in the first region, including forming the oxygen capturing layer over the first region and the second region, and removing the oxygen capturing layer over the second region with a mask layer, performing an oxidizing operation from a top surface of the oxygen capturing layer to increase oxygen concentration of the oxygen capturing layer, removing the oxygen capturing layer over the first region, and forming a gate structure over the dielectric layer.

By using a conductive layer including Cu as a long lead wiring, increase in wiring resistance is suppressed. Further, the conductive layer including Cu is provided in such a manner that it does not overlap with the oxide semiconductor layer in which a channel region of a TFT is formed, and is surrounded by insulating layers including silicon nitride, whereby diffusion of Cu can be prevented; thus, a highly reliable semiconductor device can be manufactured. Specifically, a display device which is one embodiment of a semiconductor device can have high display quality and operate stably even when the size or definition thereof is increased.

The present disclosure relates to an integrated chip comprising a substrate. A first conductive wire is over the substrate. A second conductive wire is over the substrate and is adjacent to the first conductive wire. A first dielectric cap is laterally between the first conductive wire and the second conductive wire. The first dielectric cap laterally separates the first conductive wire from the second conductive wire. The first dielectric cap includes a first dielectric material. A first cavity is directly below the first dielectric cap and is laterally between the first conductive wire and the second conductive wire. The first cavity is defined by one or more surfaces of the first dielectric cap.

The present disclosure provides a semiconductor device with an interconnect part and a method for forming the semiconductor device. The semiconductor device includes a first source/drain structure disposed over a carrier substrate, and a backside contact disposed over and electrically connected to the first source/drain structure. The semiconductor device also includes an interconnect part disposed over the backside contact. The interconnect part includes a lower redistribution layer electrically connected to the backside contact, and an upper redistribution layer disposed over the lower redistribution layer. The interconnect part also includes an interconnect frame disposed between and electrically connected to the lower redistribution layer and the upper redistribution layer. The interconnect part further includes a passivation structure surrounding the interconnect frame.

A method and structure for forming an enhanced metal capping layer includes forming a portion of a multi-level metal interconnect network over a substrate. In some embodiments, the portion of the multi-level metal interconnect network includes a plurality of metal regions. In some cases, a dielectric region is disposed between each of the plurality of metal regions. By way of example, a metal capping layer may be deposited over each of the plurality of metal regions. Thereafter, in some embodiments, a self-assembled monolayer (SAM) may be deposited, where the SAM forms selectively on the metal capping layer, while the dielectric region is substantially free of the SAM. In various examples, after selectively forming the SAM on the metal capping layer, a thermal process may be performed, where the SAM prevents diffusion of the metal capping layer during the thermal process.