Abstract: A fully aligned via interconnect structure and techniques for formation thereof using subtractive metal patterning are provided. In one aspect, an interconnect structure includes: metal lines Mx?1; metal lines Mx disposed over the metal lines Mx?1; and at least one via Vx?1 fully aligned between the metal lines Mx?1 and the metal lines Mx, wherein a top surface of at least one of the metal lines Mx?1 has a stepped profile. In another aspect, another interconnect structure includes: metal lines Mx?1; metal lines Mx disposed over the metal lines Mx?1; at least one via Vx?1 fully aligned between the metal lines Mx?1 and the metal lines Mx; and sidewall spacers alongside the metal lines Mx. A method of forming an interconnect structure is also provided.

Abstract: A semiconductor interconnect structure having a first electrically conductive structure having a plurality of bottom portions; a dielectric capping layer, at least a portion of the dielectric capping layer being in contact with a first bottom portion of the plurality of bottom portions; and a second electrically conductive structure in electrical contact with a second bottom portion of the plurality of bottom portions. A method of forming the interconnect structure is also provided.

Abstract: A resistive random access memory (RRAM) device and a method for constructing the device is described. A capping layer structure is provided over a bottom contact where the capping layer includes a recess situated over the bottom contact. A first portion of the recess is filled with a lower electrode such that the width of the recess defines the width of the lower electrode. A second portion of the recess is filled with a high-K layer so that a bottom surface of the high-K layer has a stepped profile. A top electrode is formed on the high-K layer and a top contact is formed on the top electrode. The width of the high-K layer is greater than the width of the lower electrode to prevent shorting between the top contact and the lower electrode of the RRAM device.

Abstract: A semiconductor device structure includes a metallization stack that has one or more patterned metal layers in a logic area and a memory area. At least one memory device is disposed above the metallization stack. A first level logic metal layer is coupled to a patterned metal layer of the one or more patterned metal layers in the logic area. A first level memory metal layer is formed above the first level logic metal layer and is coupled to a top electrode of the memory device stack. A distance between the one or more patterned metal layers in the logic area and the first level logic metal layer is smaller than the distance between the one or more patterned metal layers in the memory area and the first level memory metal layer.

Abstract: A semiconductor structure includes an interlayer dielectric layer, a first set of back-end-of-line interconnect structures disposed in the interlayer dielectric layer, and a second set of back-end-of-line interconnect structures at least partially disposed in the interlayer dielectric layer. Each of the first set of back-end-of-line interconnect structures has a first width and a first height providing a first aspect ratio. Each of the second set of back-end-of-line interconnect structures has a second width and a second height providing a second aspect ratio different than the first aspect ratio. The second width is greater than the first width, and the second height is different than the first height.

Abstract: A semiconductor structure includes a substrate. A first metallization layer is disposed on the substrate. A second metallization layer is disposed on the first metallization layer and having one or more openings, wherein at least one of the one or more openings is configured to expose a top surface of the first metallization layer. A polymer-adhering liner layer is disposed on sidewalls of the at least one of the one more openings in the second metallization layer. A dielectric polymer is disposed in the at least one of the one or more openings in the second metallization layer and on the polymer-adhering liner layer. The dielectric polymer is configured to seal an air gap in the dielectric polymer.

Abstract: Integrated chips and methods of forming the same include forming a conductive layer over a lower conductive line. The conductive layer is etched to form a via on the lower conductive line. A first insulating layer is formed around the via. The first insulating layer is etched back to a height below a height of the via. An upper conductive line is formed on the via, making contact with at least a top surface and a side surface of the via.

Abstract: Techniques are provided to fabricate metal interconnects using liner planarization-free process flows. A sacrificial layer is formed on a dielectric layer, and the sacrificial and dielectric layers are patterned to form an opening in the dielectric layer. A conformal liner layer is deposited, and a metal layer deposited to form a metal interconnect in the opening. An overburden portion of the metal layer is planarized to expose an overburden portion of the liner layer. A first wet etch is performed to selectively remove the overburden portion of the liner layer. A second wet etch process is performed to selectively remove the sacrificial layer, resulting in extended portions of the liner layer and the metal interconnect extending above a surface of the dielectric layer. A dielectric capping layer is formed to cover the sidewall and upper surfaces of the extended portions of the liner layer and the metal interconnect.

Abstract: A memory device, and a method of forming the same, includes a bottom electrode above an electrically conductive structure, the electrically conductive structure is embedded in an interconnect dielectric material. A magnetic tunnel junction stack located above the bottom electrode is formed by a magnetic reference layer above the bottom electrode, a tunnel barrier layer above the magnetic reference layer, and a laterally-recessed magnetic free layer above the tunnel barrier layer. Sidewall spacers surround the laterally-recessed magnetic free layer for confining an active region formed by the laterally-recessed magnetic free and the tunnel barrier layer.

Abstract: A method for making a semiconductor apparatus includes forming a first bottom interconnect in a device area of a first dielectric layer; fabricating a device on top of the first bottom interconnect; capping the device with a first interlayer dielectric; exposing a logic area of the first dielectric layer that is adjacent to the device area by removing a portion of the first interlayer dielectric from the first dielectric layer while leaving another portion of the first interlayer dielectric that caps the device; and forming a second bottom interconnect in the logic area of the first dielectric layer. By forming the second bottom interconnect after the device fabrication and capping, damage to the device and to the second bottom interconnect is avoided.

Abstract: A resistance switching RAM logic device is presented. The device includes a pair of resistance switching RAM cells that may be independently programed into at least a low resistance state (LRS) or a high resistance state (HRS). The resistance switching RAM logic device may further include a shared output node electrically connected to the pair of resistance switching RAM cells. A logical output may be determined from the programmed resistance state of each of the resistance switching RAM cells.

Abstract: An aluminum alloy wheel for a vehicle is provided, which includes: a wheel central portion, a rim portion, and a plurality of radial elements, wherein the aluminum alloy wheel is processed by centrifugal casting and forging to form a central portion with a morphology exhibiting a grain size variation with decreasing gradient in a lateral direction from an inner side of the wheel central portion to an outer side thereof.

Abstract: A device relates to a semiconductor device. The semiconductor device includes a narrow-line bamboo microstructure integrated within a metal layer of the semiconductor device and a narrow-line polycrystalline microstructure. The narrow-line polycrystalline microstructure is integrated within the same metal layer as the narrow-line bamboo microstructure.

Abstract: Embodiments of the present invention disclose a method forming a via and a trench. By utilizing a first etching process, a first metal layer of a multi-layered device to form a via, wherein the multi-layered device comprises the first metal layer and a second metal layer, wherein the first metal layer is formed directly on top of the second metal layer, wherein the second metal layer acts as an etch stop for the first etching process, wherein the first etching process does not affect the second metal layer. By utilizing a second etching process, the second metal layer of the multi-layered device to form a trench, wherein first metal layer is not affected by the second etching process, wherein the first etching process and the second etching process are two different etching process.

Abstract: An integrated circuit structure is provided. The integrated circuit structure includes a back end of line (BEOL) wiring layer including metal lines and a first area between the metal lines. The integrated circuit structure also includes a metal-insulator-metal (MIM) capacitor formed in the first area. The MIM capacitor includes a first electrode, a first dielectric layer formed on the first electrode, a second electrode formed on the first dielectric layer, a second dielectric layer formed on the second electrode, a third electrode formed on the second dielectric layer, a third dielectric layer formed on the third electrode, a fourth electrode formed on the third dielectric layer, a first metal interconnect electrically connecting the first electrode and the third electrode, and a second metal interconnect electrically connecting the second electrode to the fourth electrode.

Abstract: A semiconductor device includes a base structure including a lower level via and a lower level dielectric layer, a conductive pillar including an upper level line and an upper level via disposed on the lower level via, and a protective structure disposed between the lower level via and the upper level line. The protective structure includes a material having an etch rate less than or equal to that of the lower level via.

Abstract: After forming a contact opening in a dielectric material layer located over a substrate, a metal liner layer comprising a nitride of an alloy and a metal contact layer comprising the alloy that provides the metal liner layer are deposited in-situ in the contact opening by sputter deposition in a single process and without an air break. Compositions of the metal liner layer and the metal contact layer can be changed by varying gas compositions employed in the sputtering process.

Abstract: Embodiments of the invention include a method for fabricating a semiconductor device and the resulting structure. Mandrels are patterned on a liner, where the liner is located on a semiconductor substrate. Spacers are formed on sidewalls of the mandrels. Dielectric material lines are formed on exposed surfaces of the liner and within a plurality of gaps between the spacers. The mandrels are removed. The at least one of the dielectric material lines are removed from within at least one of the plurality of gaps between the spacers. Conductive metal is formed within each gap. The conductive metal is patterned to form metal interconnect lines and vias. The plurality of spacers and the remaining dielectric material lines are removed.

Abstract: Techniques are provided to fabricate semiconductor devices. For example, a method includes forming an interconnect structure having a base, a first conductive metal layer disposed on the base; and a first hardmask layer disposed on the first conductive metal layer. Metal lines are formed by subtractive etching. The metal lines have negative tapered sidewalls, and an opening is formed between adjacent metal lines. A first interlevel dielectric layer is deposited in the openings. A portion of the first interlevel dielectric layer is removed to form trench openings having positive tapered sidewalls. A dielectric layer is deposited in one of the openings. A liner layer and a second conductive metal layer are deposited in the other trench openings. The liner layer and the second conductive metal layer are recessed. A second hardmask layer is deposited on a top surface of the liner layer and the second conductive metal layer.

Abstract: Techniques are provided to fabricate metal interconnects using liner planarization-free process flows. A sacrificial layer is formed on a dielectric layer, and the sacrificial and dielectric layers are patterned to form an opening in the dielectric layer. A conformal liner layer is deposited, and a metal layer deposited to form a metal interconnect in the opening. An overburden portion of the metal layer is planarized to expose an overburden portion of the liner layer. A first wet etch is performed to selectively remove the overburden portion of the liner layer. A second wet etch process is performed to selectively remove the sacrificial layer, resulting in extended portions of the liner layer and the metal interconnect extending above a surface of the dielectric layer. A dielectric capping layer is formed to cover the sidewall and upper surfaces of the extended portions of the liner layer and the metal interconnect.