Embodiments of the present disclosure provide a method for forming a hole structure in a semiconductor device. The method for forming a hole structure having a first hole portion and a second hole portion connected to and over the first portion in a stack structure of a semiconductor device includes determining a hard mask layer. An etching resistivity of the hard mask layer may be inversely proportional to a difference between a first lateral dimension of the first hole portion and a second lateral dimension of the second hole portion, and the first lateral dimension may be less than the second lateral dimension. The method may also include forming the hard mask layer over the stack structure, and patterning the hard mask layer to form a first patterned hard mask layer that has a first mask opening. The first mask opening may have the first lateral dimension. The method may further include removing a portion of the stack structure exposed by the first patterned hard mask layer to form an initial hole structure in the stack structure, and patterning the first patterned hard mask layer to form a second patterned mask layer that has a second mask opening. The second mask opening may have the second lateral dimension. The method may further include removing another portion of the stack structure exposed by the second patterned hard mask layer to form the hole structure.

Disclosed are integrated circuit (IC) structure embodiments with a three-dimensional (3D) metal-insulator-metal capacitor (MIMCAP) in back-end-of-the-line (BEOL) metal levels. The MIMCAP includes a plurality of high aspect ratio trenches that extend through at least one relatively thick dielectric layer within the metal levels. Conformal layers of a metal, an insulator and another metal line the trenches and cover the top of the dielectric layer in the area of the MIMCAP. Different configurations for the bottom and top electrode contacts can be used including, for example, one configuration where the top electrode contact is a dual-damascene structure within an ultra-thick metal (UTM) level above the MIMCAP and another configuration where both the top and bottom electrode contacts are such dual-damascene structures. Also disclosed are method embodiments for forming IC structures with such a MIMCAP and these method embodiments can be readily integrated into current BEOL processing, including UTM-level dual-damascene processing.

Disclosed are integrated circuit (IC) structure embodiments with a three-dimensional (3D) metal-insulator-metal capacitor (MIMCAP) in back-end-of-the-line (BEOL) metal levels. The MIMCAP includes a plurality of high aspect ratio trenches that extend through at least one relatively thick dielectric layer within the metal levels. Conformal layers of a metal, an insulator and another metal line the trenches and cover the top of the dielectric layer in the area of the MIMCAP. Different configurations for the bottom and top electrode contacts can be used including, for example, one configuration where the top electrode contact is a dual-damascene structure within an ultra-thick metal (UTM) level above the MIMCAP and another configuration where both the top and bottom electrode contacts are such dual-damascene structures. Also disclosed are method embodiments for forming IC structures with such a MIMCAP and these method embodiments can be readily integrated into current BEOL processing, including UTM-level dual-damascene processing.

A method of forming a semiconductor device having a vertical metal line interconnect (via) fully aligned to a first direction of a first interconnect layer and a second direction of a second interconnect layer in a selective recess region by forming a plurality of metal lines in a first dielectric layer; and recessing in a recess region first portions of the plurality of metal lines such that top surfaces of the first portions of the plurality of metal lines are below a top surface of the first dielectric layer; wherein a non-recess region includes second portions of the plurality of metal lines that are outside the recess region.

The present disclosure provides a semiconductor device. The semiconductor device includes a substrate having a first conductive pattern and a conductive mask disposed over the first conductive pattern. The semiconductor device further includes a second conductive pattern disposed over the conductive mask, and electrically connecting with the first conductive pattern through the conductive mask. The conductive mask has a lower etch rate to a predetermined etchant than the second conductive pattern. A method for forming the semiconductor device is also provided.

A method includes bonding a first wafer to a second wafer, with a first plurality of dielectric layers in the first wafer and a second plurality of dielectric layers in the second wafer bonded between a first substrate of the first wafer and a second substrate in the second wafer. A first opening is formed in the first substrate, and the first plurality of dielectric layers and the second wafer are etched through the first opening to form a second opening. A metal pad in the second plurality of dielectric layers is exposed to the second opening. A conductive plug is formed extending into the first and the second openings.

A method of forming an integrated circuit includes: forming a dielectric layer, a hard mask layer, a film layer and a photoresist layer; and patterning the photoresist layer to form a via mask, where the via mask is oversized, such that the via mask extends across opposing sides of a metal line mask in the hard mask layer. The method further includes: etching the film layer and the dielectric layer based on the patterned photoresist layer; ashing the photoresist layer and the film layer; etching the dielectric layer based on a pattern of the hard mask layer to provide a via region and a metal line region; etching the hard mask layer and the dielectric layer; and performing a plurality of dual damascene process operations to form a via in the via region and a metal line in the metal line region in the integrated circuit.

A method of forming an integrated circuit structure includes forming an etch stop layer over a conductive feature, forming a dielectric layer over the etch stop layer, forming an opening in the dielectric layer to reveal the etch stop layer, and etching the etch stop layer through the opening using an etchant comprising an inhibitor. An inhibitor film comprising the inhibitor is formed on the conductive feature. The method further includes depositing a conductive barrier layer extending into the opening, performing a treatment to remove the inhibitor film after the conductive barrier layer is deposited, and depositing a conductive material to fill a remaining portion of the opening.

A method includes forming a carbon-containing layer with a carbon atomic percentage greater than about 25 percent over a first hard mask layer, forming a capping layer over the carbon-containing layer, forming a first photo resist over the capping layer, and etching the capping layer and the carbon-containing layer using the first photo resist as a first etching mask. The first photo resist is then removed. A second photo resist is formed over the capping layer. The capping layer and the carbon-containing layer are etched using the second photo resist as a second etching mask. The second photo resist is removed. A third photo resist under the carbon-containing layer is etched using the carbon-containing layer as etching mask. A dielectric layer underlying the third photo resist is etched to form via openings using the third photo resist as etching mask. The via openings are filled with a conductive material.

A semiconductor structure includes a conductive feature, a first metal-based etch-stop layer over the underlying structure, a metal-free etch-stop layer over the first metal-based etch-stop layer, a second metal-based etch-stop layer over the metal-free etch-stop layer, an interlayer dielectric layer over the second metal-based etch-stop layer, and an interconnect structure extending through the first metal-based etch-stop layer, metal-free etch-stop layer, and the second metal-based etch-stop layer, wherein a bottom portion of the conductive interconnect structure directly contacts the conductive feature. The first metal-based etch-stop layer may include a first metallic component having one of aluminum, tantalum, titanium, or hafnium, and the second metal-based etch-stop layer may include a second metallic component the same as or different from the first metallic component. The first metal-based etch-stop layer and the second metal-based etch-stop layer may both be free of silicon.