Abstract: A semiconductor device structure and a method for forming a semiconductor device structure are provided. The semiconductor device structure includes a metal gate stack over a substrate and an epitaxial structure over the substrate. The semiconductor device structure also includes a conductive contact electrically connected to the epitaxial structure. A topmost surface of the metal gate stack is vertically disposed between a topmost surface of the conductive contact and a bottommost surface of the conductive contact. The semiconductor device structure further includes a first conductive via electrically connected to the metal gate stack. The topmost surface of the conductive contact is vertically disposed between a topmost surface of the first conductive via and a bottommost surface of the first conductive via. In addition, the semiconductor device structure includes a second conductive via electrically connected to the conductive contact.

Abstract: A memory cell includes a bottom electrode, a memory element, spacers, a selector and a top electrode. The memory element is located on the bottom electrode and includes a first conductive layer, a second conductive layer and a storage layer. The first conductive layer is electrically connected to the bottom electrode. The second conductive layer is located on the first conductive layer, wherein a width of the first conductive layer is smaller than a width of the second conductive layer. The storage layer is located in between the first conductive layer and the second conductive layer. The spacers are located aside the second conductive layer and the storage layer. The selector is disposed on the spacers and electrically connected to the memory element. The top electrode is disposed on the selector.

Abstract: A memory device includes a memory cell, a protection coating, and a first sidewall spacer. The memory cell is disposed over an inter-metal dielectric (IMD) layer. The memory cell includes a bottom electrode, a top electrode and a resistance-switchable structure between the top electrode and the bottom electrode. The protection coating is on an outer sidewall of the resistance-switchable structure. The protection coating consists of a binary compound of carbon and hydrogen. The first sidewall spacer is on an outer sidewall of the protection coating. The first sidewall spacer has a greater nitrogen atomic concentration than the protection coating.

Abstract: A semiconductor device includes a channel structure, a first gate structure straddling the channel structure, and an epitaxial structure. The epitaxial structure is adjacent to the first gate structure and is coupled to an end of the channel structure. The semiconductor device further includes a first contact structure disposed over and in contact with the epitaxial structure and a nitride-based conformal layer extending at least over the first contact structure. The semiconductor device further includes an oxide-based layer disposed over the nitride-based conformal layer. A portion of the nitride-based conformal layer, disposed over the first contact structure, has a dip that is filled with a first portion of the oxide-based layer.

Abstract: A phase change random access memory (PCRAM) device includes a memory cell overlying an inter-metal dielectric (IMD) layer, a protection coating, and a first sidewall spacer. The memory cell includes a bottom electrode, a top electrode and a phase change element between the top electrode and the bottom electrode. The protection coating is on an outer sidewall of the phase change element. The first sidewall spacer is on an outer sidewall of the protection coating. The first sidewall spacer has a greater nitrogen atomic concentration than the protection coating. The protection coating forms a first interface with the phase change element. The first interface has a first slope at a first position and a second slope at a second position higher than the first position, the second slope is different from the first slope.

Abstract: A semiconductor device includes a channel structure, a first gate structure straddling the channel structure, and an epitaxial structure. The epitaxial structure is adjacent to the first gate structure and is coupled to an end of the channel structure. The semiconductor device further includes a first contact structure disposed over and in contact with the epitaxial structure and a nitride-based conformal layer extending at least over the first contact structure. The semiconductor device further includes an oxide-based layer disposed over the nitride-based conformal layer. A portion of the nitride-based conformal layer, disposed over the first contact structure, has a dip that is filled with a first portion of the oxide-based layer.

Abstract: A semiconductor device includes source/drain contacts, a gate structure, a gate dielectric cap, an etch stop layer, and a gate contact. The source/drain contacts are over a substrate. The gate structure is laterally between the source/drain contacts. The gate dielectric cap is over the gate structure and in contact with the source/drain contacts. The etch stop layer is over the source/drain contacts and the gate dielectric cap. The etch stop layer has an oxidized region directly above the gate dielectric cap. The gate contact extends through the etch stop layer and the gate dielectric cap to the gate structure. The gate contact and the oxidized region of the etch stop layer form an interface perpendicular to the substrate.

Abstract: A first interconnect structure (e.g., a gate interconnect) of a butted contact (BCT) is etched and filled. The first interconnect structure is then etched back such that a portion of the first interconnect structure is removed, then a second interconnect structure and the remaining portion of the first interconnect structure are filled. In this way, the height of the remaining portion of the first interconnect structure that is to be filled is closer to the height of the second interconnect structure when the second interconnect structure is filled relative to fully filling the second interconnect structure and fully filling the first interconnect structure in a single deposition operation. This reduces the likelihood that filling the second interconnect structure will close the first interconnect structure before the first interconnect structure can be fully filled, which may otherwise result in the formation of a void in the first interconnect structure.

Abstract: Embodiments include a contact structure and method of forming the same where the contact structure is deliberately positioned near the end of a metallic line. An opening is formed in an insulating structure positioned over the metallic line and then the opening is extended into the metallic line by an etching process. In the etching process, the line end forces etchant to concentrate back away from the line end, causing lateral etching of the extended opening. A subsequent contact is formed in the opening and enlarged opening.

Abstract: A semiconductor device includes a memory cell having a bottom electrode, a memory element, a selector, a top electrode and a connecting structure. The memory element is disposed on the bottom electrode. The selector is disposed on the memory element. The top electrode is disposed on the selector. The connecting structure is electrically connecting the memory element to the selector, wherein the connecting structure includes a base portion and a pillar portion. The base portion disposed on the memory element. The pillar portion is disposed on the base portion, wherein the pillar portion is physically connected to the selector, and includes a tapered pillar foot.

Abstract: A method includes removing a dummy gate stack to form a first trench between gate spacers, forming a replacement gate stack in the first trench, recessing the replacement gate stack to form a second trench between the gate spacers, selectively depositing a conductive capping layer in the second trench, forming a dielectric hard mask in the second trench and over the conductive capping layer, and etching the dielectric hard mask using an etching gas to form an opening in the dielectric hard mask. The replacement gate stack is revealed to the opening. The conductive capping layer is more resistant to the etching gas than the replacement gate stack. The method further comprises forming a gate contact plug over and contacting the conductive capping layer.

Abstract: A method includes removing a dummy gate stack to form a first trench between gate spacers, forming a replacement gate stack in the first trench, recessing the replacement gate stack to form a second trench between the gate spacers, selectively depositing a conductive capping layer in the second trench, forming a dielectric hard mask in the second trench and over the conductive capping layer, and etching the dielectric hard mask using an etching gas to form an opening in the dielectric hard mask. The replacement gate stack is revealed to the opening. The conductive capping layer is more resistant to the etching gas than the replacement gate stack. The method further comprises forming a gate contact plug over and contacting the conductive capping layer.

Abstract: A memory cell includes a bottom electrode, a memory element, a selector, a top electrode and a connecting structure. The memory element is disposed on the bottom electrode. The selector is disposed on the memory element. The top electrode is disposed on the selector. The connecting structure is electrically connecting the memory element to the selector, wherein the connecting structure includes a base portion and a pillar portion. The base portion disposed on the memory element. The pillar portion is disposed on the base portion, wherein the pillar portion is physically connected to the selector, and includes a tapered pillar foot.

Abstract: A memory cell includes a bottom electrode, a memory element, spacers, a selector and a top electrode. The memory element is located on the bottom electrode and includes a first conductive layer, a second conductive layer and a storage layer. The first conductive layer is electrically connected to the bottom electrode. The second conductive layer is located on the first conductive layer, wherein a width of the first conductive layer is smaller than a width of the second conductive layer. The storage layer is located in between the first conductive layer and the second conductive layer. The spacers are located aside the second conductive layer and the storage layer. The selector is disposed on the spacers and electrically connected to the memory element. The top electrode is disposed on the selector.

Abstract: A semiconductor device includes a gate structure, source/drain regions, source/drain contacts, a gate dielectric cap, an etch stop layer, and a gate contact. The gate structure is over a substrate. The source/drain regions are at opposite sides of the gate structure. The source/drain contacts are over the source/drain regions, respectively. The gate dielectric cap is over the gate structure and has opposite sidewalls interfacing the source/drain contacts.

Abstract: Embodiments include a contact structure and method of forming the same where the contact structure is deliberately positioned near the end of a metallic line. An opening is formed in an insulating structure positioned over the metallic line and then the opening is extended into the metallic line by an etching process. In the etching process, the line end forces etchant to concentrate back away from the line end, causing lateral etching of the extended opening. A subsequent contact is formed in the opening and enlarged opening.

Abstract: A semiconductor structure includes a contact plug on a source/drain region of a transistor, and a via on the contact plug. The via includes a lower portion and an upper portion over the lower portion, the lower portion of the via tapers upward, and the upper portion of the via tapers downward. The semiconductor structure further includes a metal line on the via.

Abstract: A first interconnect structure (e.g., a gate interconnect) of a butted contact (BCT) is etched and filled. The first interconnect structure is then etched back such that a portion of the first interconnect structure is removed, then a second interconnect structure and the remaining portion of the first interconnect structure are filled. In this way, the height of the remaining portion of the first interconnect structure that is to be filled is closer to the height of the second interconnect structure when the second interconnect structure is filled relative to fully filling the second interconnect structure and fully filling the first interconnect structure in a single deposition operation. This reduces the likelihood that filling the second interconnect structure will close the first interconnect structure before the first interconnect structure can be fully filled, which may otherwise result in the formation of a void in the first interconnect structure.

Abstract: Conductive contacts, methods for forming the same, and semiconductor devices including the same are disclosed. In an embodiment, a semiconductor device includes a first interlayer dielectric (ILD) layer over a transistor structure; a first contact extending through the first ILD layer, the first contact being electrically coupled with a first source/drain region of the transistor structure, a top surface of the first contact being convex, and the top surface of the first contact being disposed below a top surface of the first ILD layer; a second ILD layer over the first ILD layer and the first contact; and a second contact extending through the second ILD layer, the second contact being electrically coupled with the first contact.

Abstract: A memory cell includes a bottom electrode, a memory element, spacers, a selector and a top electrode. The memory element is located on the bottom electrode and includes a first conductive layer, a second conductive layer and a storage layer. The first conductive layer is electrically connected to the bottom electrode. The second conductive layer is located on the first conductive layer, wherein a width of the first conductive layer is smaller than a width of the second conductive layer. The storage layer is located in between the first conductive layer and the second conductive layer. The spacers are located aside the second conductive layer and the storage layer. The selector is disposed on the spacers and electrically connected to the memory element. The top electrode is disposed on the selector.